61749749 nordberg redbook
TRANSCRIPT
Performance dataof Crushing Equipment
Red bookElectronic version AGD - 11/96
Gyratory CrushersCapacities (30-60 / 42-70)............................................................ 3Capacities (48-75 / 54-75)............................................................ 4Capacities (60/90 - 60/110) .......................................................... 5Capacities (72-112) ...................................................................... 6Curves - setting 150mm / 125mm / 115mm / 100mm .................. 7Curves - setting 230mm / 205mm / 180mm / 150mm.................. 8Dimensions of Gyratory Crushers (drawing) ................................ 9Dimensions of Gyratory Crushers (table)................................... 10
GYRATORY CRUSHERS CAPACITIESOPERATING DATA (SHORT TONS)
CRUSHERSIZEA-B
INCH (MM)
MAXIMUNDESIGNHORSE-POWER
CTRSHAFTRPM
GYRPERMIN
ECCTHROW
INCH(mm)
OPEN SIDE DISCHARGE SETTING - C INCH (mm)
4(100
4 1/2(115)
5(125)
5 1/2(140)
6(150
6 1/2(165)
7(180)
7 1/2(190)
8(205)
8 1/2(215)
9(230)
9 1/2(240)
10(255)
30-60(762-15254)
250 450 190
3/4 (19) 470 580 690 780
7/8 (22) 570 680 820 950
1 (25) 640 780 930 1050
1 1/4 (32) 800 970 1170 1290
42-70(1067-1778) 400 600 160
3/4 (19) 690 750 820 880 960 1030 1100
1 (25) 910 1010 1110 1210 1320 1430 1550
1 1/8 (29) 1130 1240 1370 1500 1630 1770
1 1/4 (32) 1360 1460 1720 1860 2000
Capacities (30-60 / 42-70)
CRUSHERSIZEA-B
INCH (MM)
MAXIMUNDESIGNHORSE-POWER
CTRSHAFTRPM
GYRPERMIN
ECCTHROW
INCH(mm)
OPEN SIDE DISCHARGE SETTING - C INCH (mm)
4(100)
4 1/2(115)
5(125)
5 1/2(140)
6(150)
6 1/2(165)
7(180)
7 1/2(190)
8(205)
8 1/2(215)
9(203)
9 1/2(240)
10(255)
48-75(1219-1905) 500 514 140
1 1/4 (32) 1230 1420 1540 1780 1970 2190 2430
1 3/8 (35) 1370 1500 1680 1920 2160 2410 2660
1 1/2 (38) 1620 1820 2080 2340 2600 2880
1 5/8 (41) 1700 1950 2230 2520 2810 3110
54-75(1372-1905) 500 514 140
1 1/4 (32) 1140 1330 1530 1750 1970 2190 2420
1 3/8 (35) 1240 1460 1670 1910 2140 2390 2640
1 1/2 (38) 1580 1830 2090 2350 2620 2900
1 5/8 (41) 1690 1960 2250 2550 2840 3160
Capacities (48-75 / 54-75)
CRUSHERSIZEA-B
INCH (MM)
MAXIMUNDESIGNHORSE-POWER
CTRSHAFTRPM
GYRPERMIN
ECCTHROW
INCH(mm)
OPEN SIDE DISCHARGE SETTING - C INCH (mm)
4(100)
4 1/2(115)
5(125)
5 1/2(140)
6(150)
6 1/2(165)
7(180)
7 1/2(190)
8(205)
8 1/2(215)
9(230)
9 1/2(240)
10(255)
60-90(1524-2286)
700 514 130
1 3/8 (35) 2130 2360 2590 2830 3060 3310 3570
1 1/2 (38) 2310 2560 2610 3060 3330 3610 3880
1 8/8 (41) 2480 2730 2990 3260 3530 3800 4090
1 3/4 (44) 2620 2940 3250 3570 3920 4260 4600
60-110(1524-2794) 1000 514 115
1 1/2 (38) 3480 3640 3810 3990 4160 4350 4530
1 5/8 (41) 3740 3930 4130 4330 4530 4740 4960
1 3/4 (44) 3990 4200 4430 4660 4890 5130 5380
2 (51) 4510 4740 4970 5210 5450 5700 5960
Capacities (60/90 - 60/110)
Capacities (72-112)
CRUSHERSIZEA-B
INCH (MM)
MAXIMUNDESIGNHORSE-POWER
CTRSHAFTRPM
GYRPERMIN
ECCTHROW
INCH(mm)
OPEN SIDE DISCHARGE SETTING - C INCH (mm)
4(100)
4 1/2(115)
5(125)
5 1/2(140)
6(150)
6 1/2(165)
7(180)
7 1/2(190)
8(205)
8 1/2(215)
9(203)
9 1/2(240)
10(255)
72-112(1829-2845)
1400 514 115
1 1/2 (38) 3050 3440 3820 4230 4630 5060 5480
1 5/8 (41) 3300 3710 4130 4570 5020 5480 5940
1 3/4 (44) 3500 3930 4360 4810 5280 5730 6210
2 (51) 3920 4430 4930 5450 5980 6520 7080
Curves - setting 150mm / 125mm / 115mm / 100mm
Curve 01: Setting 150 mmCurve 02: Setting 125 mmCurve 03: Setting 115 mmCurve 04: Setting 100 mm (eruptive)
0102
03
04
Curves - setting 230mm / 205mm / 180mm / 150mm
Curve 01: Setting 230 mmCurve 02: Setting 205 mmCurve 03: Setting 180 mmCurve 04: Setting 150 mm (eruptive)
0102
03
04
B
AB
A G
L K
E
F
JDisch. Opening
C
D
M
N
See Note 2
SeeNote 1
See Note 3
Notes:1. Minimum distance for removal of eccentric or hydraulic support.2. Minimum distance for countershaft removal.3. Foundation bolts not furnished unless ordered separately.
Dimensions of Gyratory Crushers (drawing)
30-60(762-1524)
42-70(1067-1778)
48-75(1219-1905)
54-75(1372-1905)
60-90(15242286)
60-110(1524-2794)
72-112(1825-2845)
A 8'-0"(2438)
9'-0"(2743)
10'-8"(3251)
10-'8"(3251)
14'-0"(4267)
14'-8"(4470)
20'-8"(6096)
B 9'-8"(2946)
11'-3"(3429)
13'-4"(4064)
13'-4"(4064)
16'-4"(4877)
16'-9"(5105)
21'-4"(6502)
C 4'-5"(1346)
3'-9"(1143)
3'-9 1/4"(1149)
3'-10 1/4"(1175)
4'-10 3/4"(1494)
4'-11"(1499)
4'-1 1/2"(1257)
D 8'-10 1/2"(2705)
12'-9 3/4"(3905)
14'-0 5/8"(4283)
14'-11 1/2"(4559)
17'-9 5/8"(5425)
19'-2"(5842)
21'-5 1/2"(6540)
E 5'-10"(1524)
6'-1"(1854)
6'-11"(2108)
6'-11"(2108)
8'-11"(2718)
8'-11"(2718)
10'-1"(3073)
F 6'-8"(2032)
7'-8 3/8"(2346)
8'-10 1/2"(2705)
8'-10 1/2"(2705)
10'-7 1/4"(3231)
10'-3"(3124)
12'-1"(3683)
G 13'-6 1/2"(4128)
17'-4 1/4"(5290)
19'-2 1/2"(5855)
20'-2 3/8"(6156)
24'-2 1/8"(7371)
25'-1"(7645)
27'-3"(8306)
H 10'-3"(3124)
13'-5"(4089)
15'-1"(4597)
16'-10"(5131)
19'-1"(5817)
19'-11"(6071)
22'-8'(6909)
J 9'-0"(2743)
10'-12"(3099)
12'-6"(3810)
12'-6"(3810)
14'-8"(4470)
15'-5"(4699)
17'-3 1/2"(5270)
K 7'-1"(2159)
8'-4"(2540)
8'-7 1/4"(2623)
8'-7 1/4"(2623)
10'-0 5/8"(3063)
10'-2 1/4"(3105)
12'-8"(3861)
L 3'-5"(1041)
4'-8"(1422)
5'-5 1/4"(1657)
5'-5 1/4"(1657)
6'-4 3/8"(1940)
6'-4 3/8"(1940)
8'-5"(2565)
M 2'-2"(660)
5'-7 5/8"(1718)
6'-3 5/8"(1921)
7'-2 1/4"(1921)
7'-10 1/4"(2190)
7'-10 1/4"(2394)
8'-4 1/4"(2546)
N 15'5 1/2"(4712)
23'-10 3/8"(7274)
24'-1 1/2"(7353)
25'- 1 3/8"(7655)
29'-10" 5/8"(9108)
33'-10 3/8"(10322)
33'-11 1/4"(10344)
Dimensions of Gyratory Crushers (table)
VB single toggle jaw crushersPerformance tables .................................................................... 12Typical product gradations ......................................................... 13VB jaw crusher specifications .................................................... 14Dimensions (mm) ....................................................................... 15
Performance tables
VB 92 VB 46 VB 57 VB 67 VB 0806 VB 1008 VB 1210 VB 1311 VB 1512 VB 1613
30 mm with 12% rejects 18 to 23 7 to 9
40 mm with 12% rejects 23 to 30 9 to 12 12 to 18
50 mm with 12% rejects 30 to 38 12 to 15 18 to 23 30 to 38
60 mm with 12% rejects 38 to 45 15 to 18 23 to 27 38 to 45
70 mm with 12% rejects 45 to 53 18 to 23 27 to 33 45 to 53 60 to 75
80 mm with 12% rejects 53 to 60 33 to 42 53 to 60 70 to 85
90 mm with 12% rejects 42 to 45 60 to 68 80 to 95 95 to 120
100 mm with 12% rejects 68 to 75 90 to 110 110 to 140 140 to 170
120 mm with 12% rejects 110 to 125 140 to 170 170 to 205 210 to 250
140 mm with 12% rejects 110 to 140 170 to 215 205 to 250 260 to 320 270 to 370
170 mm with 12% rejects 210 to 265 260 to 320 320 to 390 350 to 460
200 mm with 12% rejects 270 to 330 315 to 330 390 to 470 410 to 550 410 to 550
240 mm with 12% rejects 380 to 460 480 to 570 520 to 670 520 to 670
280 mm with 12% rejects 570 to 670 600 to 780 600 to 780
320 mm with 12% rejects 700to1100
Typical product gradations
ROUND OPENING O
SQUARE OPENING
VB jaw crusher specifications
CRUSHER SIZES VB 92 VB 46 VB 57 VB 67 VB 0806 VB 1008 VB 1210 VB 1311 VB 1512 VB 1613
Size of feed opening - length mm 920 460 570 670 800 1000 1150 1300 1500 1600
Size of feed opening - weight mm 250 250 300 410 600 800 800 1100 1200 1300
Total weight of crusher(without feed chute)
kg 7650 2650 5700 8100 14500 18800 28000 42900 89000 96000
Weight of feed chute kg 90 100 120 175 970 860 1070 2400 1770 1770
Weight of one jaw kg 2 x 160 160 170 320 1090 1530 2600 3600 4 x 825 4 x 825
Rotation speed of crusher revs per min 355 450 370 355 305 225 225 205 180 180
Slip ring motorPower 1500 REVS per min
kw 37 to45
18,5to 22
22 to30
37 to45
55 to 75 90 to 110 110 to 132 132 to 160 160 to 200 200
Drive : V-beltsnumber and size 6 spc 3 spc 5 spc 6 spc 5 spc 6 spc 6 spc 8 spc 9 spc 10 spc
belt length mm 5005 4750 5005 5005 7100 8500 8500 1000 11800 11800
Weight of heaviest component kg 500 500 500 500 1500 2000 3000 4000 3000 3000
Maximum lift for maintenance kg 3000 1000 2500 3000 5000 10000 15000 20000 30000 30000
Hydraulic controls:- jaw remova- toggle replacement- setting
---
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-optionoption
-stdstd
-stdstd
-stdstd
stdstdstd
stdstdstd
Jaws:
- number of parts for each jaw 2 1 1 1 1 1 1 1 4 4
- characteristics R* R* R* R* R* R*-1 R*-1 R*-1 R*-1 R*-1
Dimensions (mm)
SIZE A B C D E F G H I J K L M N O P
46 2500 1310 860 932 20 735 752 490 450 300 517 615 345 270 410 1242
57 3100 1561 1050 1080 20 724 875 465 490 170 710 890 470 330 190 1340
67 3600 1800 1240 1320 20 795 975 525 480 400 767 930 465 375 160 1500
92 2400 1441 930 1120 10 690 890 645 410 250 892 1060 600 475 160 1535
806 4200 2320 1670 2109 20 1640 1480 990 910 350 775 960 625 425 300 1870
1008 4500 2775 1955 2273 20 1660 1700 883 975 430 865 1035 710 560 240 400
1210 6300 3085 2265 2659 20 1970 1970 1025 1100 500 970 1145 800 630 260 400
1311 7000 3605 2650 3243 20 2300 2100 1152 1455 645 1132 1412 930 720 300 400
1512 8420 4283 3150 3125 20 2045 2875 1300 1750 900 1630 1950 1150 730 555 3320
1613 8420 4300 3150 3125 20 2045 2935 1300 1750 900 1630 1950 1150 730 555 3320
C-Series jaw Crushers
Technical Data............................................................................ 17Capacities................................................................................... 18Indicative product distribution .................................................... 19Dimensions (table) ..................................................................... 20Dimensions (drawing) ................................................................ 21
Technical Data
C 63 B C 80 B C 100 B C 110 B C 125 B C 140BS C 160 B
Nominal mmfeed opening Inch
440 x 63017 x 25
530 x 80021 x32
750x100030 x40
850x110034 x44
950x125037 x 49
1070x140042 x 55
1200x160047 x 63
Power kWelectric hp
4560
75 (55)100 (75)
110 (90)150 (125)
132 (160)200
160 (132)200
200 (160)250
250 (200)300
Speed rpm 340 300 260 230 220 220 200
Length of mmstationary jaw Inch
100039
125049
160063
180071
200079
220087
250098
Max lift for maint. kg(pitman less flywheel) Ibs
20804590
41509150
706015,560
900019,840
12,96028,570
15,95035,160
21,38047,130
Total weight kgIbs
605013,340
10,90024,030
20,10044,320
25,50056,200
36,70080,910
45,30099,870
64,900143,080
Capacities
C.S.S. C 63 B C 80 B C 100 B C 110 B C 125 B C 140 BS C 160 B
mm Inch mpth stph mtph stph mthp stph mtph stph mtph stph mtph stph mtph stph
40 1-9/16 40 44
50 2 53 59 80 88
60 2-3/8 67 73 96 106
70 2- 3/4 80 88 113 124 150 165 190 209
80 3-1/8 93 103 129 142 168 185 212 225
90 3-9/16 107 117 146 160 185 204 235 256
100 4 120 132 162 178 203 224 257 287 290 319
125 5 203 223 248 272 313 350 343 377 387 426
150 6 292 321 368 412 396 436 455 501 520 572
175 7 336 370 424 475 450 494 523 575 596 656
200 8 381 419 480 537 503 553 591 650 672 739
225 9 425 468 556 611 659 725 748 823
250 10 609 670 727 800 824 906
275 11 795 875 900 990
300 12 976 1074
Indicative product distribution
NOTE:if the closed side setting (c.s.s) is 100 mm (4 in), the maximum end product sizeis approx. 160 mm (6 3/8 in) and the proportion of fraction under 50 mm (2 in) approx.35%.
Closed side setting (c.s.s.)
Percentage passing, weight %
.08 .12 .16 .2 .24 .39.31 .79 1.2 1.6 2.4 3.9 7.8 11.8 15.7 (in)
Screen hole size (mm*mm)
Dimensions (table)
C 63 B C 80 B C 100 B C 110 B C 125 B C 140BS C 160 B
A mmInch
160063
195077
240094,5
2670105
2900114
3060121
3550140
B mmInch
110043
135053
170067
200079
210083
226089
2650104
C mmInch
195077
240095
2880113
2665105
3370105
3645133
4200165
D mmInch
112044
136754
172568
181071
209082
236093
2540100
E mmInch
138955
170867
225089
238594
2688106
2890114
3182125
F mmInch
1606
2008
24510
38015
45018
45018
45018
G mmInch
52521
66526
81832
95037
107342
117246
131552
H mmInch
100039
120047
140055
150059
160063
160063
180071
J mmInch
76030
94037
117046
130051
147058
164065
188074
K mmInch
1646,5
1707
26710,5
25010
28011
30012
38515
Dimensions (drawing)
G-Cone Crushers
G-CONE CRUSHERS, 8 SERIES................................................. 24G 49 Capacities.......................................................................... 24G 49 curves (setting 10-8-6 mm, feed) ...................................... 25G 108 Capacities........................................................................ 26G 108 curves (setting 12-14-16 mm, feed) ................................ 27G 158 Capacities........................................................................ 28G 158 curves (setting 25-16 mm) .............................................. 29G 258 Capacities........................................................................ 30G 258 curves (setting 27-33-40 mm) ......................................... 31
G-CONE CRUSHERS, 11 SERIES............................................... 32G 411 capacities ......................................................................... 32G 811 capacities ......................................................................... 33G 411 and G 811 curves (setting 8-10-15 mm) .......................... 34G 411, G 811 curves (setting 8-11-16mm) ................................. 35G 2511 capacities ....................................................................... 36G 2511 curves (setting 25-30-35 mm) ....................................... 37G 3511 capacities ....................................................................... 38G 3511 curves (setting 35-40-45 mm) ....................................... 39
G-CONE CRUSHERS, 12 SERIES............................................... 40G 412, G 612, G 1012 capacities............................................... 40G 412 curves (setting 8-11-16mm)............................................. 41G 612 curves (setting 8 - 11 - 16 mm) ....................................... 42G 1012 curves (setting 15 - 20 - 25 mm) ................................... 43G 1812-2612-2812-3812 capacities........................................... 44G 1812 curves (setting 20 - 25 - 31 mm) ................................... 45G 2612, G 2812 curves (setting 25 - 30 - 34 mm) ..................... 46G 3812 curves (setting 30 - 35 mm) .......................................... 47
G-CONE CRUSHERS, 15 SERIES............................................... 48G 415 and G 815 capacities ...................................................... 48G 3514, 4214, 2215, 1315 capacities ........................................ 49G 3815, G 5015 capacities......................................................... 50G 415, G 815, G 1315 curves (setting 8 - 13 - 16 mm) ............. 51G 1815, G 2215 curves (setting 20 - 25 - 35 mm) ..................... 52G 5015 curve (setting 65 mm).................................................... 53
G 49 CAPACITIES
G-CONE CRUSHERS, 8 SERIES
CRUSHER / SETTING 4 6 8 10 14 FEED MAXI
G49 (TERTIARY)
30 45 50 65 70 35
G49INCREASED STROKE
(TERTIARY)35 50 60 70 80 35
G 49 CURVES (SETTING 10-8-6 MM, FEED)
CURVE 01: SETTING 6 MMCURVE 02: SETTING 8 MMCURVE 03: SETTING 10 MMCURVE 04: FEED
0
10
20
30
40
50
60
70
80
90
100
0.125 0.25 0.5 1 2 4 6 16 32 64 128
02
03
04
01
G 108 CAPACITIES
CRUSHER / SETTING 10 12 14 16 18 FEED MAXI
G108(TERTIARY)
75 80 85 90 92 60
G108INCREASED STROKE
(TERTIARY)90 95 100 100 105 60
G 108 CURVES (SETTING 12-14-16 MM, FEED)
CURVE 01: SETTING 12 MMCURVE 02: SETTING 14 MMCURVE 03: SETTING 16 MMCURVE 04: FEED
02
01
03
04
0
10
20
30
40
50
60
70
80
90
100
0.125 0.25 0.5 1 2 4 6 16 32 64 128
G 158 CAPACITIES
CRUSHER / SETTING 13 16 18 20 25 FEED MAXI
G158 - 16 65 72 78 82 92 110 MM
G158 - 20 - 90 95 100 110 110 MM
G158 - 25 - - 110 120 - 110 MM
G 158 CURVES (SETTING 25-16 MM)
01
02
CURVE 01: SETTING 25 MMCURVE 02: SETTING 16 MM
G 258 CAPACITIES
CRUSHER / SETTING 24 27 30 35 40 FEED MAXI
G258(TERTIARY)
110 115 120 130 140 200
G258INCREASED STROKE
(TERTIARY)120 125 150 160 200 200
CRUSHER/SETTING 30 35 40 45 FEED MAXI
G258(SECONDARY)
120 130 140 150 200
G258INCREASED STROKE
(SECONDARY)150 160 200 220 200
G 258 CURVES (SETTING 27-33-40 MM)
CURVE 01: SETTING 27 MMCURVE 02: SETTING 33 MMCURVE 03: SETTING 40 MM
01
02
03
0
10
20
30
40
50
60
70
80
90
100
0.125 0.25 0.5 1 2 4 6 16 32 64 128
G 411 CAPACITIES
CRUSHER / SETTING 6 10 13 16 18 20 22 FEED MAXI
G411 - 20 80 95 110 120 130 135 140 32 MM
G411 - 25 - 120 135 150 160 170 - 32 MM
G411 - 30 - 145 165 180 185 - - 32 MM
G-CONE CRUSHERS, 11 SERIES
G 811 CAPACITIES
CRUSHER / SETTING 6 10 13 16 18 20 22 FEED MAXI
G811 - 20 80 100 115 120 130 140 145 60 MM
G811 - 25 - 125 140 155 165 175 - 60 MM
G811 - 30 - - 165 185 195 - - 60 MM
G 411 AND G 811 CURVES (SETTING 8-10-15 MM)
CURVE 01: SETTING 15 MMCURVE 02: SETTING 10 MMCURVE 03: SETTING 8 MM
0102
03
G 411, G 811 CURVES (SETTING 8-11-16MM)
CURVE 01: SETTING 16 MMCURVE 02: SETTING 11 MMCURVE 03: SETTING 8 MM
01
02
03
G 2511 CAPACITIES
CRUSHER / SETTING 20 25 30 35 FEED MAXI
G2511(SECONDARY)
140 160 180 200 230
G2511INCREASED STROKE
(SECONDARY)180 240 270 300 230
G 2511 CURVES (SETTING 25-30-35 MM)
CURVE 01: SETTING 25 MMCURVE 02: SETTING 30 MMCURVE 03: SETTING 35 MMCURVE 04: SARJA 1
01
02
03
04
0
10
20
30
40
50
60
70
80
90
100
0.125 0.25 0.5 1 2 4 6 16 32 64 128
G 3511 CAPACITIES
CRUSHER / SETTING 35 40 45 50 55 FEED MAXI
G3511(SECONDARY)
150 180 200 220 240 300
G3511INCREASED STROKE
(SECONDARY)200 250 280 310 330 300
G 3511 CURVES (SETTING 35-40-45 MM)
CURVE 01: SETTING 35 MMCURVE 02: SETTING 40 MMCURVE 03: SETTING 45 MM
01
02
03
0
10
20
30
40
50
60
70
80
90
100
0.125 0.25 0.5 1 2 4 6 16 32 64 128
G 412, G 612, G 1012 CAPACITIES
CRUSHER /SETTING
6 8 10 13 16 20 22 28 FEED MAXI
G412 - 25 90 100 110 120 130 145 155 32 MM
G412 - 32 - 130 140 155 170 - - 32 MM
G412 - 40 - - 165 190 - - - 32 MM
G612 - 25 - 120 130 145 160 180 190 220 50 MM
G612 - 32 - - - 180 200 220 230 50 MM
G612 - 40 - - - 220 240 270 280 - 50 MM
G1012 - 25 - - - 150 165 180 185 210 60 MM
G1012 - 32 - - - 180 200 220 230 - 60 MM
G1012 - 40 - - - - 240 260 275 60 MM
G-CONE CRUSHERS, 12 SERIES
G 412 CURVES (SETTING 8-11-16MM)
CURVE 01: SETTING 16 MMCURVE 02: SETTING 11 MMCURVE 03: SETTING 8 MM
01
02
03
G 612 CURVES (SETTING 8 - 11 - 16 MM)
CURVE 01: SETTING 16 MMCURVE 02: SETTING 11 MMCURVE 03: SETTING 8 MM
01
0203
G 1012 CURVES (SETTING 15 - 20 - 25 MM)
CURVE 01: SETTING 25 MMCURVE 02: SETTING 20 MMCURVE 03: SETTING 15 MM
01
0203
G 1812-2612-2812-3812 CAPACITIES
CRUSHER /SETTING
20 22 28 32 36 40 46 50 53FEEDMAXI
G1812 - 25 180 185 205 215 225 230 100 MM
G1812 - 32 - 230 270 300 - - 100 MM
G1812 - 40 - - 310 350 - - 100 MM
G2612 - 25 - 185 215 240 265 290 160 MM
G2612 - 32 - - 280 300 330 160 MM
G2612 - 40 - - 330 360 - - 160 MM
G2812 - 18 200 205 220 235 245 260 280 200 MM
G2812 - 25 - - 300 320 340 360 390 200 MM
G2812 - 32 - - - 380 410 440 - 200 MM
G2812 - 40 - - - - 480 - - 200 mm
G3812 - 18 - - 140 160 180 200 230 250 270 320 MM
G3812 - 25 - - - 220 255 285 330 365 - 320 MM
G3812 - 32 - - - - 360 390 450 - - 320 MM
G3812 - 40 - - - - - 490 540 - - 320 MM
G 1812 CURVES (SETTING 20 - 25 - 31 MM)
CURVE 01: SETTING 31 MMCURVE 02: SETTING 25 MMCURVE 03: SETTING 20 MM
01
0203
G 2612, G 2812 CURVES (SETTING 25 - 30 - 34 MM)
01
02
03
CURVE 01: SETTING 34 MMCURVE 02: SETTING 30 MMCURVE 03: SETTING 25 MM
G 3812 CURVES (SETTING 30 - 35 MM)
CURVE 01: SETTING 35 MMCURVE 02: SETTING 30 MM
01
02
G 415 AND G 815 CAPACITIES
CRUSHER /SETTING
6 8 10 13 16 20 22 28 FEED MAXI
G415 - 25 - 160 165 175 185 195 210 220 25 MM
G415 - 32 - - 190 215 225 245 255 - 25 MM
G415 - 40 - - - 250 280 - - - 25 MM
G415 - 25 - - 160 175 185 200 208 230 55 MM
G815 - 32 - - - 220 235 250 265 - 55 MM
G815 - 40 - - - 270 290 305 - 55 MM
G-CONE CRUSHERS, 15 SERIES
G 3514, 4214, 2215, 1315 CAPACITIES
CRUSHER /SETTING
20 22 28 32 36 40 46 50 55 60 FEED
G3514 - 20 - - - - 170 240 330 370 20-300 MM
G3514 - 25 - - - - - 300 410 470 20-300 MM
G4214 - 20 - - - - - 230 300 370 400 480 20-360 MM
G4214 - 25 - - - - - 390 470 500 600 20-300 MM
G2215 -25 190 205 250 285 315 350 400 15-160 MM
G2215 -32 - 260 320 360 410 450 480 15-160 MM
G2215 - 40 - - 400 460 500 550 - 15-160 MM
CRUSHER /SETTING
12 16 20 22 28 30 32 FEED MAXI
G1315 - 25 205 230 255 270 310 320 330 15-100 MM
G1315 - 32 - 290 320 335 380 - - 15-100 MM
G1315 - 40 - - 390 410 430 - - 15-100 MM
G 3815, G 5015 CAPACITIES
CRUSHER /SETTING
35 45 50 55 60 65 70 75 80 FEED MAXI
G3815 - 18 250 330 370 400 430 470 510 540 570 300 MM
G3815 - 25 - 470 530 580 630 670 730 790 - 300 MM
G3815 - 32 - 600 670 730 780 850 930 970 - 300 MM
G5015 - 18 - 330 360 400 435 460 500 535 570 350 MM
G5015 - 25 - 460 520 560 630 670 730 780 820 350 MM
G5015 - 32 - - 650 730 780 860 910 970 - 350 MM
CRUSHER / SETTING 35 45 50 55 60 65 70 FEED MAXI
G3815-18 (SECONDARY) 250 330 370 400 430 470 510 300
G3815-25(SECONDARY))
470 530 580 630 670 730 300
G3815-32(SECONDARY) 600 670 730 780 850 930 300
G 415, G 815, G 1315 CURVES (SETTING 8 - 13 - 16 MM)
CURVE 01: SETTING 16 MMCURVE 02: SETTING 13 MMCURVE 03: SETTING 8 MM
01
0203
G 1815, G 2215 CURVES (SETTING 20 - 25 - 35 MM)
01
02
03
CURVE 01: SETTING 35 MMCURVE 02: SETTING 25 MMCURVE 03: SETTING 20 MM
G 5015 CURVE (SETTING 65 MM)
CURVE 01: SETTING 65 MM
01
Omnicone Crushers
Performances ............................................................................. 55Product curves (Omnicone in secondary application) ............... 56Product curves (Omnicone in tertiary application) ..................... 57The Omnicone crusher range .................................................... 58
Performances
MODEL TYPEFEEDSIZE
CAPACITY IN TPHAT C.S.S.
10 12 14 16 20 25 32 40 50
STDC 190 125 145 170
STDM 160 110 120 135 150
937 STDF 125 90 100 110 125
SHC 100 765 80 90 100
SHMCONSULT FACTORY
SHF
STDC 200 180 200 230
STDM 170 150 170 190
1144 STDF 130 125 140 160 180
SHC 100 90 105 120 140
SHMCONSULT FACTORY
SHF
STDC 240 300 340 380 440
STDM 195 220 250 280 310 350
1352 STDF 135 190 210 240 250
SHC 120 160 170 190 230 245
SHMCONSULT FACTORY
SHF
STDC 290 370 420 170 500
STDM 240 300 340 390 430
1560 STDF 200 240 270 300 330
SHC 140 200 220 270
SHMCONSULT FACTORY
SHF
Product curves (Omnicone in secondary application)
Typical product gradations at specified C.S.S. for hard and semi-hard stone in open circuit
Product curves (Omnicone in tertiary application)
The Omnicone crusher range
TYPE
crusher MOTOR MOTOR PULLEY DRIVE BELTS
Weightkg
Pulley
Speed (rpm) 1500 rpmkW
ØPCDmm
Widthmm
Numberof
belts
Section
Minimumbelt
lengthmm
ØPCDmm
Widthmm
937114413521560
820014 30020 00032 000
630630800
1000
161212212212
830830750750
90110160220
355355400500
161212212212
6888
SPCSPCSPCSPC
3000355040004500
Omnicone X
Spectacular results..................................................................... 60Results (curves) ......................................................................... 61Omnicone Clearance dimensions (table)................................... 62Omnicone Clearance dimensions (drawing) .............................. 63
Spectacular results
Omnicone Installed PowerThrought put
capacity MTPH
Production
Minus 10 %minus 10 %
MTPHMinimum closed circuitdimension acceptable
937 X 110 kW 100 to 110 65 68 6 mm
1144 X 160 kW 150 to 160 57 88 8 mm
1352 X 220 kW 250 to 270 45 117 12 mm
The gradations and capacities are dependant on the feed gradation, the crushing chamber, the material density,the material cleanliness, its moisture and its crushability.
Results (curves)
AVERAGE GRADATIONS
OMNICONE X TERTIARY APPLICATION (% passing through a square mesh, depending on thesetting)
Omnicone Clearance dimensions (table)
Model937 1144 1352 1560
mm mm mm mm
A Maintframe flange 760 910 1060 1225
B Maintframe flange 760 910 1060 1215
C Maintframe flange 760 910 1060 1225
D Maintframe hub diameter 400 480 500 580
E To bottom of maintenance hub 120 60 160 140
F To bottom of oil piping 286 216 324 323
G To top of dust collar (hyraulic) 1200 1435 1535 1785
HAdjustment ring maximumdiamenter
1760 2180 2540 2850
JClearance for countershaftremoval
1700 2000 2310 2530
K To end of countershaft 1107 1290 1525 1640
LMaximum height to top of feedhopper
1520 1810 1880 2216
M Inside diameter of feed hopper 970 1146 1392 1586
N To top of feed plate 1021 1316 1407 1730
O Overall height (L + F) 1806 2026 2204 2539
POverall height of bowl assembly(long std inter protrude belowbow)
882 965 1005 1140
QAdjustment cap maximumdiameter (hydraulic)
1590 1870 2070 2276
RClearance for bowl assemblyremoval
2090 2410 2540 2930
S Overall height of head assembly 720 865 945 1150
T Head/mantle maximum diameter 970 1150 1345 1560
UClearance for head assemblyremoval
1935 2325 2470 2930
V Maximum overall crusher width 1880 2410 2710 3026
WAdditional upward travel duringclearing stroke
80 76 90 122
X Mounting hole location 545 660 830 883
Y Mounting hole diameter 56 60 65 64
Z Overall width including pulley 2090 2370 2750 2992
Omnicone Clearance dimensions (drawing)
64
Omnicone SX
Performances .............................................................................................................. 65Product curves (secondary application) ....................................................................... 66Product curves (tertiary application)............................................................................. 67Dimensions (table)....................................................................................................... 68Dimensions (drawing) .................................................................................................. 69Technical information ................................................................................................... 70
65
Performances
CAPACITY IN MTPH AT CSS
MACHINE 10 13 16 19 22 25 32 38 45 51
937 SX 90/ 110 120/ 140 140/ 160 150/ 170 160/ 190 170/ 200 190/ 220 210/ 240
1144 SX 150/ 180 180/ 210 200/ 230 220/ 250 230/ 270 250/ 290 300/ 350 350/ 400
1352 SX 240/ 270 270/ 300 290/ 330 310/ 350 320/ 370 400/ 460 450/ 520
1560 SX 520/ 580 570/ 630 620/ 680
MACHINE 937 SX 1144 SX 1352 SX 1560 SX
Installed power, kW 132 160 / 200 200 / 250 250 / 315
Maximum feed size, mm 200 250 300 350
66
Product curves (secondary application)
OMNICONE SXSecondary application passing through a square mesh, depending on the setting.
The gradations and capacities shown are dependant on the feed gradation, the crushing chamber, the material density,the material cleanliness, its moisture and its crushability.
67
Product curves (tertiary application)
OMNICONE SXTertiary application passing through a square mesh, depending on the setting.
The gradations and capacities shown are dependant on the feed gradation, the crushing chamber, the material density,the material cleanliness, its moisture and its crushability.
68
Dimensions (table)
Model
937SX
1144SX
1352SX
1560SX
mm mm mm mm
A Mainframe flange 760 910 1060 1225
B Mainframe flange 760 910 1060 1215
C Mainframe flange 760 910 1060 1225
D Mainframe hub diameter 400 480 500 580
E To bottom of mainframe hub 120 60 160 140
F To bottom of oil piping 286 216 324 323
G To top of dust collar(Hydraulic) 1200 1435 1535 1785
HAdjustment ring maximumdiameter 1760 2180 2540 2850
JClearance for countershaftremoval 1700 2000 2310 2530
K To end of countershaft 1107 1290 1525 1640
LMaximum height to top of feedhopper 1520 1810 1880 2216
M Inside diameter of feed hopper 970 1146 1392 1586
N To top of feed plate 1021 1316 1407 1730
O Overall height (L + F) 1806 2026 2204 2539
POverall height of bowlassembly (long std linerprotudes below bowl)
882 965 1005 1140
QAdjustment capmaximum diameter(Hydraulic)
1590 1870 2070 2276
RClearance for bowl assemblyremoval 2090 2410 2540 2930
S Overall height of headassembly 720 865 945 1150
T Head / mantle maximumdiameter 970 1150 1345 1560
UClearance for head assemblyremoval 1935 2325 2470 2930
V Maximum overall crusherwidth 1880 2410 2710 3026
W Additional upward travelduring clearing stroke 80 76 90 122
X Mounting hole location 545 660 830 883
Y Mounting hole diameter 56 60 65 64
Z Overall width including pulley 2090 2370 2750 2992
69
Dimensions (drawing)
70
Technical information
TYPE
CRUSHER MOTOR
WeightKg
PulleyCountershaftSpeed (mm)
1 500 rpmkW
Ø PCDWidthmm
937 SX 8 600 500 212 1050 132
1144 SX 14 300 710 212 1050 160 / 200
1352 SX 20 000 800 263 940 200 / 250
1560 SX 32 000 800 263 830 250 / 315
Weights complete crusher and assemblies .................................. 72Crusher capacities ........................................................................ 73Product curves (secondary application HP200 - HP300) ............. 74Product curves (tertiary application HP200 - HP300) ................... 75Dimensions ................................................................................... 76
HP Cone crushers
Weights complete crusher and assemblies
HP200 SX HP300 SX HP400 SX HP500 SX HP700 SX
Kg Lbs Kg Lbs Kg Lbs Kg Lbs Kg Lbs
Crusher Complete 10.350 22.800 15.400 33.900 21.800 48.000 30.000 66.000 61.900 136.500
Bowl, Bowl liner, Adj.Cap, Hopper
2.585 5.695 3.230 7.115 4.800 10.575 7.200 15.800 16.350 36.050
Head, Mantle and Feedplate
1.050 2.315 1.825 4.020 3.240 7.130 4.900 10.700 8.720 19.200
Recommended Power145KW
200HP
220KW
300HP
300KW
400HP
375KW
500HP
450KW
600HP
Countershaft SpeedRPM
900 / 1200 900 / 1200 850 / 1050 770 / 951 740 / 913
Crusher capacities
Open Circuit - Peak Capacity Metric Tons/Hour Short Tons/Hour
Closed Side Setting, mm/in.
SIZE 10mm 3/8" 13mm 1/2" 16mm 5/8" 19mm 3/4" 22mm 7/8" 25mm 1" 32mm 1"1/4 38mm 1"1/2 45mm 1"3/4 51mm 2"
HP200SX
90 - 120100 - 130
120 - 150130 - 165
140 - 180155 - 200
150 - 190165 - 210
160 - 200175 - 220
170 - 220185 - 240
190 - 235210 - 260
210 - 250230 - 275
HP300SX
115 - 140125 - 155
150 - 185165 - 205
180 - 220200 - 240
200 - 240220 - 265
220 - 260240 - 285
230 - 280255 - 310
250 - 320275 - 355
300 - 380330 - 420
350 - 440385 - 485
HP400SX
140 - 175155 - 195
185 - 230205 - 255
225 - 280250 - 310
255 - 320280 - 355
275 - 345305 - 380
295 - 370325 - 410
325 - 405360 - 445
360 - 450395 - 495
410 - 515450 - 570
465 - 580510 - 640
HP500SX
175 - 220195 - 240
230 - 290255 - 320
280 - 350310 - 385
320 - 400355 - 440
345 - 430380 - 475
365 - 455400 - 500
405 - 505445 - 555
445 - 555490 - 610
510 - 640560 - 705
580 - 725640 - 800
HP700SX
260 - 325285 - 360
325 - 410360 - 450
385 - 480425 - 530
435 - 545480 - 600
470 - 590520 - 650
495 - 620545 - 685
545 - 680600 - 750
600 - 750660 - 825
690 - 865760 - 955
785 - 980865 - 1080
For Range of Work Index = 13 to 16 kWh/stFor Range of Work Index = 14 to 18 kWh/st
Product curves (secondary application HP200 - HP300)
Average product gradations in open circuit for hard medium material*
Secondary application
* The gradations and capacities shown are dependant on the feed gradation, the crushing chamber, the materialdensity, the material cleanliness, its moisture and its crushability.
% passing through a square mesh depending on the setting
Product curves (tertiary application HP200 - HP300)
Average product gradations in open circuit for hard medium material*
Tertiary application
* The gradations and capacities shown are dependant on the feed gradation, the crushing chamber, the materialdensity, the material cleanliness, its moisture and its crushability.
% passing through a square mesh depending on the setting
Dimensions
HP200 SX HP300 SX HP400 SX HP500 SX HP700 SX
mm in mm in mm in mm in mm in
A To bottom of oil piping 290 11 - 3/8 270 10 - 5/8 240 9 - 1/2 425 16 - 3/4 688 27 - 1/8
B Adjustment ring maximumdiameters
1.760 69 - 1/4 2.020 79 - 1/2 2.370 93 - 3/8 2.730 107-1/2 3.390 133-1/2
CClearance required forremoving countershaftassembly
1.865 73 - 3/8 2.020 79 - 1/2 2.470 97 - 1/4 2.650 104-3/8 3.450 135-13/16
D To end of countershaft 1.160 45 - 5/8 1.350 53 - 1/8 1.645 64 - 3/4 1.760 69 - 1/4 2.225 87 - 5/8
E Maximum height to top 1.605 63 - 1/4 1.890 73 - 3/8 2.055 80 - 7/8 2.290 90 - 1/8 3.279 129-1/8
F Inside diameter of feedhopper
940 37 1.104 43 - 1/2 1.308 51 - 1/2 1.535 60 - 1/2 1.816 71 - 1/2
HClearance required forremoving bowl assembly
2.155 84 - 7/8 2.460 96 - 7/8 2.650 104-3/8 3.300 129-7/8 3.880 154-3/4
I Clearance required forremoving head assembly
2.115 83 - 1/4 2.430 95 - 5/8 2.715 106-7/8 3.165 124-5/8 3.777 148-11/16
JAdditional upward travel offeed hopper duringclearing stroke
76 3 98 3 - 7/8 105 4 - 1/8 125 4-15/16 179 7-1/16
KMounting hole location*5-1/2 FT - **7FT
545 21 - 1/2 660 26 830 32-11/16 882 34 - 3/41.1301.245
44 - 1/2*49**
LMain frame dischargeopening diameter
1.220 48 1.490 59 1.726 68 2.040 80 - 1/2 2.400 94 - 1/2
Note : 'L' not shown in dimension drawing
Main characteristics ...................................................................... 78Crushing cavity selection .............................................................. 79Crusher capacities ........................................................................ 80Average product gradations.......................................................... 81
HP100SX Cone Crusher
Main characteristics
Complete crusher weight : 5500 kg (12120 Lbs)Recommended power : 75-90 kW (100-125 HP)Countershaft speed : 850-1200 RPM
Overall dimensionsLength : 2060 mm (82")Width : 1505 mm (60")Height : 1290 mm (51")
Crushing cavity selection
* The minimum setting is the setting which will cause ring bouce. It can change depending on rockcharacteristics and crusher speed.
Maximum feed size Minimum setting Minimum closed circuit (#)
COARSE 150 mm (6") 16 mm (5/8") 20 mm (3/4")
MEDIUM 70 mm (2 3/4") 10 mm (3/8") 10 mm (3/8")
FINE 40 mm (1 9/16") 8 mm (5/16") 6 mm (1/4")
EXTRA FINE 25 mm (1") 6 mm (1/4") 2 mm (8 mesh)
*
Crusher capacities
Setting mm (in) 6 (1/4") 8 (5/16") 10 (3/8") 13 (1/2") 16 (5/8") 19 (3/4") 22 (7/8") 25 (1") 28 (1 1/8") 32 (1 1/4")
Capacity MT/hCapacity ST/h
45-5550-60
50-6055-65
55-7060-75
60-8065-80
70-9075-100
75-9580-105
80-10085-110
85-11090-120
90-120100-135
100-140110-155
Average product gradations
% c
umul
ativ
e pa
ssin
g
mm
* The gradations and capacities shown are dependent on feed gradation, crushing chamber, material density,material cleanliness, moisture and crushability.
(8) (4) (1/4) (3/8) (3/4) (2) (4) (in or Tyler mesh)
Crushing Cavity Selection ............................................................. 83Crusher capacities ........................................................................ 84Product gradations ........................................................................ 85
MP Series Cone crushers
Crushing Cavity Selection
STANDARD SHORTHEAD
CrusherSize
Type ofCavity
Minimumsetting
"A"
Feed opening withminimum recommended
discharge setting AMinimumsetting
"A"
Feed opening withminimum
recommendeddischarge setting A
BClosed side
BOpen side
BClosed
side
BOpenside
MP1000
Fine16mm0.63"
215mm8.50"
280mm11.00"
10mm0.38"
25mm1.00"
90mm3.50"
Medium25mm1.00"
290mm11.50"
345mm13.50"
10mm0.38"
82mm3.25"
147mm5.75"
Coarse32mm1.26"
340mm13.37"
387mm15.25"
13mm0.50"
127mm5.00"
191mm7.50"
MP800
Fine19mm0.75"
241mm9.50"
282mm11.10"
7mm0.27"
40mm1.57"
91mm3.58"
Medium25mm0.98"
308mm12.08"
347mm13.66"
10mm0.39"
77mm3.03"
127mm5.00
Coarse32mm1.26"
343mm13.52"
383mm15.10"
12mm0.47"
113mm4.45"
162mm6.38
A
B
Crusher capacities
Open Circuit-Peak Capacity in Metric Tons/Hour-Short Tons/Hour
Standard Capacities
Standardsetting
20mm0.79"
25mm0.98"
30mm1.18"
35mm1.38"
40mm1.57"
45mm1.77"
50mm1.97"
55mm2.17"
MP1000
MTPH720/880
900/1100
1080/1320
1260/1540
1440/1760
1620/1980
1800/2200
1980/2420
STPH793/970
992/1212
1190/1455
1389/1697
1587/1940
1785/2182
1984/2424
2182/2667
MP800
MTPH576/704
720/880
864/1056
1008/1232
1152/1408
1296/1584
1440/1760
1584/1936
STPH635/776
793/970
952/1164
1111/1358
1270/1552
1428/1746
1587/1940
1746/2133
Shorthead Capacities
ShortheadSetting
10mm0.39"
12mm0.47"
14mm0.55"
16mm0.63"
18mm0.71"
20mm0.79"
22mm0.87"
24mm0.94"
MP1000
MTPH530/648
563/688
596/728
629/769
662/809
695/849
728/890
761/930
STPH584/714
620/758
657/803
693/847
730/892
766/936
802/981
839/1025
MP800
MTPH424/518
450/550
477/583
503/615
530/647
556/679
582/712
609/744
STPH467/571
496/606
525/642
554/678
584/713
613/748
641/785
671/820
Product gradations
Average Product Gradations in open circuits for Hard and Medium MaterialSecondary Application
Average Product Gradations in open circuits for Hard and Medium MaterialTertiary Application
SCREEN SIZE
SCREEN SIZE
PE
RC
EN
T P
AS
SIN
GP
ER
CE
NT
PA
SS
ING
% P
assi
ng t
hrou
gh a
squ
are
mes
h de
pend
ing
on t
he s
ettin
g.
* The
gra
datio
ns a
nd c
apac
ities
sho
wn
are
depe
ndan
t on
the
feed
grad
atio
n, th
e cr
ushi
ng c
ham
ber,
the
mat
eria
l den
sity
, the
mat
eria
lcl
eanl
ines
s, it
s m
oist
ure
and
its c
rush
abili
ty.
% P
assi
ng t
hrou
gh a
squ
are
mes
h de
pend
ing
on t
he s
ettin
g.
* The
gra
datio
ns a
nd c
apac
ities
sho
wn
are
depe
ndan
t on
the
feed
grad
atio
n, th
e cr
ushi
ng c
ham
ber,
the
mat
eria
l den
sity
, the
mat
eria
lcl
eanl
ines
s, it
s m
oist
ure
and
its c
rush
abili
ty.
19.1(.75")
38.1(1.5")
76(3.0")
26.9(1.06")
53.9(2.12")
9.50(.375")
19(.75")
13.5(.53")
26.9(1.06")
Range............................................................................................ 87Open circuit performance.............................................................. 88Closed circuit performance ........................................................... 89Average granulometric scale for aggregate product, open circuit 90Dimensions ................................................................................... 91
Symons cone crushers
Range
TYPE
STANDARD
BCS 2' BCS 3' BCS 4' BCS 4' 1/4 BCS 5' 1/2 BCS 7' HD
CRUSHER
Weight kg 4600 10600 16800 21000 44600 18120
Heaviestcomponent
kg 1270 2630 4650 5210 12000 18120
Driven pulley
pulley mm 533 762 915 915 915 -
width mm 137 227 300 372 510 -
Countershaft speed rpm 575 580 485 485 485 435
MOTOR
Speed 1500 rpm
Power kw 30 75 90 132 200 300
MOTOR PULLEY
Pulley mm 210 305 306 306 306 -
Width mm 148 240 300 359 359 -
V BELTS
Number 5 6 8 10 10 -
Section mm 22 x 14 32 x 19 32 x 19 32 x 19 32 x 19 -
Belt length m 4,163 5,023 6,863 6,863 6,863 -
TYPESHORTHEAD
BCS 2' BCS 3' BCS 4' 1/4 BCS 5' 1/2 BCS 7' HD BCS 7' XHD
CRUSHER
Weight kg 4900 10900 21500 45250 70200 89600
Heaviestcomponent
kg 1270 2630 5210 12000 18120 25050
Driven pulley
pulley mm 533 762 915 915 - -
width mm 137 227 372 510 - -
Countershaft speed rpm 575 580 485 485 435 525
MOTOR
Speed 1500 rpm
Power kw 30 75 132 200 300 370
MOTOR PULLEY
Pulley mm 210 305 306 306 - -
Width mm 148 240 359 359 - -
V BELTS
Number 5 6 10 10 -
Section mm 22 x 14 32 x 19 32 x 19 32 x 19 -
Belt length m 4,163 5,023 6,863 6,863 -
These indicative figures and specifications aresubject to change without notice.
These indicative figures and specifications aresubject to change without notice.
Open circuit performance
Production tph at respective settings
6,3 10 12,5 16 20 25 32 40 50 63
16 19 22 27 33
19 22 27 33 45 54
22 27 36 50 63
36 45 54 65 75 90
50 65 85 105 125
90 115 135 160
85 105 130 160 180
105 130 160 190 225
140 175 215 245 270
150 190 220 260 300
100 125 150 180 200 225
150 180 210 245 280
200 230 280 320
215 250 290 330 370
215 250 290 320 345
270 330 370 410
280 340 400 450 580
420 470 610
380 500 620 730
610 730 810 1000
790 840 1090 1270
880 1180 1360
Production tph at respective settings
3 5 6 8 10 13 16 19 25
15 18 22 25 35
15 18 22 25 35
25 35 40 52 62 75
35 42 55 65 80 95
47 60 75 92 110 120
70 85 105 125 145
60 72 90 105 125 145
72 95 110 130 150
120 150 170 190 210
160 180 200 225
105 135 160 190 210
145 170 200 225 240
210 235 255 280
255 275 300
190 270 320 360 400
360 400 450 500
450 480 540 600
500 590 650
CONSULT FACTORY FOR CAPACITES
Open circuit SHORTHEAD
Size CavityMinimum
recommendedsetting A
Aperture at minimumsetting A Maximum
recommendedsetting A'
Aperture at minimumsetting A'
closedB
openB
closedB'
openB'
2' SH610 mm
Fine 5 27 40 13 34 47
Croase 5 38 50 13 45 56
3' SH914 mm
Fine 3 12 40 31 40 65
Medium 5 33 60 25 42 71
Croase 6 50 76 25 69 91
Extra-croase 8 65 90 20 77 102
4' 1/4 SH1295 mm
Fine 5 28 63 59 82 117
Medium 6 42 72 59 79 109
Croase 9 74 106 53 118 150
Extra-croase 13 103 135 46 136 174
5' 1/2 SH1676 mm
Fine 6 36 71 54 84 119
Medium 8 57 87 54 102 132
Croase 12 100 131 44 124 155
Extra-croase 16 150 184 44 178 212
7' SH2100 mm
HB
Fine 5 51 98
Medium 10 95 133
Croase 13 127 178
Extra-croase 16 152 203
7' SH2134 mm
XHBCONSULT FACTORY FOR CAPACITES
Open circuit STANDARD
Size CavityMinimum
recommendedsetting A
Aperture at minimumsetting A Maximum
recommendedsetting A'
Aperture at minimumsetting A'
closedB
openB
closedB'
openB'
2' ST610 mm
Fine 6 56 71 19 64 80
Croase 8 78 93 38 103 114
Extra-croase 11 100 111 38 118 128
3' ST914 mm
Fine 10 103 115 43 125 140
Croase 13 124 143 37 148 165
Extra-croase 19 180 196 37 198 211
4' ST1219 mm
Fine 12 130 144 61 173 187
Medium 15 157 176 63 215 230
Croase 19 182 204 80 250 265
Extra-croase 21 216 237 56 251 273
4' 1/4 ST1295 mm
Fine 13 131 150 62 180 199
Medium 20 205 224 62 253 272
Croase 22 229 253 50 258 280
Extra-croase 25 242 270 68 290 310
5' 1/2 ST1676 mm
Fine 19 196 208 78 238 250
Medium 22 219 241 92 289 311
Croase 25 251 276 76 302 327
Extra-croase 38 343 368 82 387 412
7' ST2100 mm
HB
Fine 19 270 292
Medium 25 308 340
Croase 32 340 375
Extra-croase 38 425 460
Closed circuit performance
Open circuit SHORTHEAD
Size CavityMinimum
recommendedsetting A
Aperture at minimumsetting A Maximum
recommendedsetting A'
Aperture at minimumsetting A'
closedB
openB
closedB'
openB'
2' SH610 mm
Fine 5 27 40 13 34 47
Croase 5 38 50 13 45 56
3' SH914 mm
Fine 3 12 40 31 40 65
Medium 5 33 60 25 42 71
Croase 6 50 76 25 69 91
Extra-croase 8 65 90 20 77 102
4' 1/4 SH1295 mm
Fine 5 28 63 59 82 117
Medium 6 42 72 59 79 109
Croase 9 74 106 53 118 150
Extra-croase 13 103 135 46 136 174
5' 1/2 SH1676 mm
Fine 6 36 71 54 84 119
Medium 8 57 87 54 102 132
Croase 12 100 131 44 124 155
Extra-croase 16 150 184 44 178 212
7' SH2134 mm
HB
Fine 5 51 105
Medium 10 95 133
Croase 13 127 178
Extra-croase 16 152 203
7' SH2134 mm
XHBCONSULT FACTORY FOR CAPACITES
Production tphn based in closed circuit operation :
5 6.3 10 12,5 16 20 25
Recommended setting for closed circuit
5 6 8 10 13 16 19
1 2 1 2 1 2 1 2 1 2 1 2 1 2
10 18 12 20 19 24 22 27 30 38
10 18 12 20 19 24 22 27 30 38
23 38 24 44 45 57 54 68 64 82
23 38 28 46 47 60 57 71 68 88 81 104
31 52 51 66 66 82 78 100 93 120 108 132
60 77 75 93 90 115 107 137 131 159
40 66 48 80 78 100 92 115 107 137 125 160
48 80 82 105 97 120 110 143 128 165
105 132 128 165 145 187 171 209
137 176 155 200 180 220
75 115 115 150 141 176 163 209 180 231
125 160 150 187 172 220 193 247 216 264
180 231 201 258 230 280
219 280 248 302
145 208 218 327 286 354 327 408 381 454
286 381 327 454 381 500 454 544
345 490 408 590 500 600
422 617 500 626
CONSULT FACTORY FOR CAPACITES
NB : these figures are for materials with a density of1.6.Feed size, material hardness and moisture content offeed all affect capacity.
Column 1 gives tph finished product (screenundersize).
Column 1 gives tph passing through the crusher.
Under certain conditions the SYSMONSStandard Cone Crusher can be operated inclosed circuit. We will pleased to study anyspecific application you may have.
Flow 2
Screen
Flow 1
B and B 1
A and A 1
Rec
ircul
atin
g lo
ad
Average granulometric scale for aggregate product, open circuit
ROUND OPENING Ø
SQUARE OPENING
1 2 3 4 5 6 7 8 9 10 20 30 40 50 60 70 80 90 100
Dimensions
DIMENSIONS (mm)
TYPE L h A B C D E F G H J K M Ø
2' ST
1801 1718 1375 1350 1050 368 990 90 550 1334 950 84 838 45
2' SH
3' ST
2232 2390 1705 1960 1235 430 1320 226 702 1524 1040 178 1057 58
3' SH
4' ST 2560 3192 2161 2613 1435 579 1664 298 823 1867 902 192 1202 64
4' 1/4 ST
2731 3201 2340 2623 1472 578 1766 298 900 2020 1012 192 1225 64
4' 1/4 ST
5' 1/2 ST
3912 3974 2896 3180 2236 794 2260 370 1100 2896 1388 227 1520 76
5' 1/2 SH
7' ST 1879
4622 4470 3683 3429 - 1041 2490 - 1347 3302 - 1803 102
7' SH 1193
B
Ø
Gyradisc crushers
Capacities ..................................................................................... 93Curves (for Gyr 36"-Gyr 48") ......................................................... 94Dimensions ................................................................................... 95
Capacities
CAPACITY1
TOTALCRUSHER
STPH
CAPACITY 2 in MTPH / STPH
RECOMMENDED SCREEN SIZE
9mm.375"
6mm.250"
5mm.185"
3mm.131"
2mm.093"
1.6mm.065"
1mm.046"
.833mm.0328"
ASTMC-33SPECSAND
GYR36 65/75
54/60 45/50 31/35 27/30 20/23 16/18 13/15 9/1020/25STPH
4'x12'SD 4'x12'SD 4'x14'SD 5'x14'DD 5'x14'DD 6'x14'DD 6'x20'DD 6'x20'DD
GYR48 115/130
94/105 72/80 49/55 40/45 36/40 27/30 22/25 15/1734/40STPH
4'x12"SD 5'x14'SD 6'x16'SD 6'x20'DD 6'x20'DD 8'x20'DD 8'x20'DD2 Req.
6'x16'DD
GYR66 190/210
144/160 108/120 76/85 63/70 54/60 40/45 36/40 22/2555/60STPH
5'x12'SD 6'x20'SD 8'x20'SD2 Req.
6'x16'DD2 Req.
6'x16'DD2 Req.
6'x20'DD3 Req.
6'x16'DD2 Req.
8'x20'DD
GYR84 265/300
225/250 162/180 117/130 90/100 81/90 63/70 54/60 36/4080/70STPH
6'x14'SD 8'x20'SD2 Req.
6'x20'SD2 Req.
6'x20'DD2 Req.
6'x20'DD2 Req.
8'x20'DD2 Req.
8'x20'DD4 Req.
6'x16'DD
SURGEBIN
Closed circuit
Recirculatingload
Capacity 1
Capacity 2
Curves (for Gyr 36"-Gyr 48")
0.2 0.3 0.4 0.5 0.6 0.7 1 2 3 4 5 6 7 8 9 10 20 30 40 50 60
ROUND OPENING Ø
SQUARE OPENING
Dimensions
BA
C
J
H
G
D
E F
Gyradisc CrusherDesignation Head
DiameterA
(mm)B
(mm)C
(mm)D
(mm)E
(mm)F
(mm)G
(mm)H
(mm)J
(mm)English Metric
36" GD 900 GD36"
914mm2121 3366 1051 2238 1422 686 546 540 1321
48" GD 1200 GD48"
1219mm2537 4039 1308 2654 1664 876 799 686 1765
66" GDHD
1650 GD66"
1676mm2977 3804 1543 3324 2464 1028 793 800 2260
84" GDHD
2100 GD84"
2134mm3645 5344 1800 3775 2962 1353 1029 902 2489
84" GDXHD
2100 GD84"
2134mm3629 5492 1949 3664 2962 1353 1029 902 2489
Impact crushers (BP-HSI)
Quarry application guide ............................................................ 97Main characteristics (BP horizontal shaft impactors) ............... 102BP curves ................................................................................. 103Capacities - BP 1007 ............................................................... 104Capacities - BP 1010 ............................................................... 105Capacities - BP 1013 ............................................................... 106Capacities - BP 1310 ............................................................... 107Capacities - BP 1313 ............................................................... 108Capacities - BP 1315 ............................................................... 109Capacities - BP 1620 ............................................................... 110Main characterisitics (HSI) ........................................................111HSI curves................................................................................ 112Capacities - HSI 1007 .............................................................. 113Capacities - HSI 1010 .............................................................. 114Capacities - HSI 1013 .............................................................. 115Capacities - HSI 1310 .............................................................. 116Capacities - HSI 1313 .............................................................. 117Capacities - HSI 1315 .............................................................. 118Capacities - HSI 1620 .............................................................. 119Estimation of hammer wear life (HSI) ...................................... 120
Quarry application guide
PRIMARY APPLICATIONS
Rock characteristics
According to French standards :
- abrasion index less than 250 g/t
- crushability more than 35%
- dynamic fragmentation more than 20%
- compressive strength less than 1 800kg/cm2 (test done with cylinder of rock 40 mm diameterand 80 mm high).
According to US standards :
- paddle abrasion index less than 0.0240 g
- Los Angeles abrasion index more than 20 %
- average impact work index less than 16maximum impact work index less than 23.
Main kinds of rock : Limestones, dolomitic limestone, gypsum, talc, chalk, marbles, marl,schists, slates
Hammer materials in primary applications
. Manganese steel
The property of this alloy is to be hardened superficially by the rock blows and to remainductile in the heart.This is the only kind of alloy enabling primary application use without breakage.Hammer life duration is not easily predictable and of course the homogeneity of the quarryface (see life duration of wear parts) ; paddle abrasion index gives only an idea of what willbe the wear parts life duration.Results from sites shows that hammers can last 200 hours for abrasion index of 250 g/t(A.index. of 0.024 g) and up to more than 2 000 hours for not abrasive limestones. (Seechart about estimation of hammer wear life).
. Other materials
In some application cases (i.e. with soft rocks, maximum feed size controlled to avoid too bigblocks and no tramp iron,), it might be interesting to use martensitic steel or chrome ironhammers as far as life duration is concerned.Chrome iron material is much more harder than manganese steel and then much more brittle.This means that feed material must be well prepared and controlled as well as tramp ironotherwise breakages are bound to happen.Martensitic steel material is in between manganese and chrome iron as far as ductility andhardness ; breakage might happen.In case of abrasive material, it could be profitable, economically speaking and talking intoaccount some breakages, to use such type of hammer material.
Improvement of life duration comparing to manganese:
1.2 to 1.5 times for martensitic steel2 to 4 times for chrome iron
SECONDARY APPLICATIONS
Rock characteristics
According to French standards :
- abrasion index less than 900 g/t
- crushability more than 30%
- dynamic fragmentation more than 15%
According to US standards :
- paddle abrasion index less than 0.2100 g
- Los Angeles abrasion index more than 15 %
- average impact work index less than 20maximum impact work index less than 26.
Horizontal shaft impactor has not to be used when more abrasive or tougher rock has to beprocessed.
Main kinds of rock : Same as for primary applications plus dolomite, some granites and
basalts, sandstone, medium abrasive gravels and ores.
Hammer materials in secondary applications
. Manganese steel
Used when paddle abrasion index is less than 250 g/t (A. index less than 0.024g.). Hammerduration life is from 200 hours up to more than 1 500 hours for not abrasive limestones.
. Chrome iron
When paddle abrasion index is more than 250 g/t, chrome iron hammers become necessary.A secondary application top feed size allows the use of such material although a breakagemight happen in case of tramp iron ; see performances chart for maximum top feed sizewhen using chrome iron.A protection by means of metal detector is necessary to prevent tramp iron to go through themachine.Hammer life duration is from 150 hours up to more than 2 000 hours depending on rocksprocessed and on impactor working conditions.
IMPACTOR FEED
The quarry run is composed by 30% to 60% of rocks having half dimension of the maximumnominal size.Bulk density is considered to be 1.6 g/cm3.
Rule of thumb for quarry blocks:
- 3 dimensions represent the size of a bloc : thickness, the nominal size and length; thicknessis about 0.6 times the nominal size and length is about 1.6 times the nominal size.
- See performances charts for weight of blocks and maximum top feed size.
MAXIMUM REDUCTION RATIO IN OPEN CIRCUIT
Refer to performances charts : the limit to get the final product size in open circuit is indicated.
MAXIMUM REDUCTION RATIO IN CLOSED CIRCUIT
Refer to performances charts :In closed circuit, finer product size than indicated in the charts can be obtained but therecirculating load might be too large.
CAPACITIES IN OPEN AND CLOSED CIRCUITS
Refer to performances charts and average output curves.N.B. a product size has 90% passing at the corresponding square opening.
POWER TO BE INSTALLED
Refer to performances charts : power mentioned is maximum power to install according toprimary or secondary application.
ROTATION SPEED
Refer to performances charts.
ADJUSTMENT OF THE BREAKER PLA TES
- Second breaker plate setting
To be adjusted to the nominal product size dimension.
- First breaker plate setting
Setting = (Top feed size + second breaker plate setting) / 4 + 20 mm.
- Example : top feed size : 1000 mmproduct size : minus 80 mm
Second breaker plate setting : 80 mmFirst breaker plate setting : (100 + 80) / 4 + 20 = 290 mm.
- During commissioning
These above theoritical setiings have to be adjusted if required to get the final requestedproduct.
HOW TO USE THE PERFORMANCES CHART
1- Choose the top feed size of the application.
2- Choose the final product size you want to get from the machine:
Several cases :
- You get directly the nominal product size in open circuit (OC), or you reach the impactorworking limit in open circuit.
- You might want to get finer product then you have to use a closed circuit (CC) at anopening sieve equal to the nominal product size. In this case the output of the impactorwill be the finer specified output you can get in open circuit.
Note :Nominal size is with 90% passing at corresponding square opening; gradation curve willbe found in the average output curves chart.
3- Capacities are basic capacities of the requested nominal product size obtained with thecorresponding electrical power. For reduced outputs, the necessary power is proportional tothe outputs reduction.
4- Rotation speed and tip hammer speed are indicated for each top feed size.
Main characteristics (BP horizontal shaft impactors)
size 1007 1010 1013 1310 1313 1315 1620
FEED OPENING
Width (mm) 750 1020 1320 1020 1320 1540 2050
Height (mm) 650 710 770 1000 1140 1140 1400
ROTOR
Diameter (mm) 1000 1000 1000 1350 1350 1350 1550
Number of hammers 4 4 4 4 4 4 5
POWER (kW) 557590
90110132
110132160
110132160
132160200
160200250
250315
2 x 200
WEIGHT (kg) 8300 10040 11970 15680 18815 21960 42500
Without feed box
BP curves
BP HORIZONTAL SHAFT IMPACTORSAVERAGE OUTPUT CURVES
90% PRODUCT PASSING AT CORRESPONDING SQUARE OPENING
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
BP 1007
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
kWrpm
mm kg
MATERIAL BULK DENSITY : 1.6MATERIAL CRUSHABILITY (FRENCH STANDARDS) : FROM 30%TO 55%
m/s 150 125 100 80 60 50 40 30 25 20 15 10
OC
CC
90740 300 x
500x 800
200OC 175 160 140 120 100*
38 CC 90 65 55 50 45
90740 240 x
400x 640
100OC 175 150 135 115 100*
38 CC 85 70 60 55 45
90780 180 x
300x 480
45OC 165 145 120 105*
41 CC 90 75 65 60 50 40
75780 120 x
200x 320
12OC 150 130 110 100*
41 CC 80 75 65 55 45
75820 60 x
100x 160
1.6OC 115 95*
43 CC 85 75 60 50
75880 30 x
50x 80
0.2OC 110 95*
46 CC 85 70 55
OC
CC
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
Capacities - BP 1007M
AX
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Capacities - BP 1010
BP 1010
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
kWrpm
mm kg
MATERIAL BULK DENSITY : 1.6MATERIAL CRUSHABILITY (FRENCH STANDARDS) : FROM 30%TO 55%
m/s 200 150 125 100 80 60 50 40 30 25 20 15
OC
CC
OC
CC
132740 360 x
600x 960
350OC 240 220 190 165 140 125*
38 CC 105 85 75 65
132740 240 x
400x 640
100OC 240 210 185 155 135*
38 CC 115 95 85 75 60
110780 180 x
300x 480
45OC 225 200 165 145*
41 CC 125 105 90 80 65
110780 120 x
200x 320
12OC 210 175 155 135*
41 CC 110 100 85 70
110820 60 x
100x 160
1.6OC 150 125*
43 CC 115 95 80
110880 30 x
50x 80
0.2OC 150 130*
46 CC 110 95
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
MA
X. P
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Capacities - BP 1013
BP 1013
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
kWrpm
mm kg
MATERIAL BULK DENSITY : 1.6MATERIAL CRUSHABILITY (FRENCH STANDARDS) : FROM 30%TO 55%
m/s 200 150 125 100 80 60 50 40 30 25 20 15
OC
CC
CC
CC
160740 360 x
600x 960
350CC 385 325 300 255 220 190 165*
38 CC 140 115 100 90
160740 240 x
400x 640
100CC 330 290 255 210 190*
38 CC 160 135 115 100 80
132780 180 x
300x 480
45CC 310 265 220 195*
41 CC 170 140 125 110 90
132780 120 x
200x 320
12CC 280 235 210 180*
41 CC 150 135 115 95
132820 60 x
100x 160
1.6CC 200 170*
43 CC 150 130 110
132880 30 x
50x 80
0.2OC 200 170*
46 CC 140 125
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
MA
X. P
OW
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Capacities - BP 1310
BP 1310
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
kWrpm
mm kg
MATERIAL BULK DENSITY : 1.6MATERIAL CRUSHABILITY (FRENCH STANDARDS) : FROM 30%TO 55%
m/s 200 150 125 100 80 60 50 40 30 25 20 15
OC
CC
160520 480 x
800x1280
800OC 360 300 270 235 205 170*
36 CC 150 130 110 95
160540 360 x
600x 960
350OC 385 325 300 255 220 190 165*
38 CC 140 115 100 90
160540 240 x
400x 640
100OC 330 290 255 210 190*
38 CC 160 135 115 100 80
132610 180 x
300x480
45OC 310 265 220 195*
43 CC 170 140 125 110 90
132610 120 x
200x 320
12OC 280 235 210 180*
43 CC 150 135 115 95
132650 60 x
100x 160
1.6OC 200 170*
46 CC 150 130 110
OC
CC
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
MA
X. P
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RO
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Capacities - BP 1313
BP 1313
TOP FEEDSIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
kWrpm
mm kg
MATERIAL BULK DENSITY : 1.6MATERIAL CRUSHABILITY (FRENCH STANDARDS) : FROM 30%TO 55%
m/s 200 150 125 100 80 60 50 40 30 25 20 15
200520 540 x
900x1440
1100OC 430 360 320 280 245 205*
36 CC 180 155 130
200520 480 x
800x 1280
800OC 450 375 335 295 260 215*
36 CC 190 165 140 120
200540 360 x
600x 960
350OC 485 420 370 325 285 240 210*
38 CC 180 150 130 110
200610 240 x
400x 640
100OC 415 365 320 270 240*
43 CC 205 170 145 125 100
160540 180 x
300x 480
45OC 385 335 280 250*
38 CC 215 180 155 135 110
160610 120 x
200x 320
12OC 360 300 270 235*
43 CC 195 170 145 120
160610 60 x
100x 160
1.6OC 255 215*
43 CC 190 160 135
OC
CC
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
MA
X. P
OW
ER
CH
RO
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IR
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SP
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CU
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Capacities - BP 1315
BP 1315
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
kWrpm
mm kg
MATERIAL BULK DENSITY : 1.6MATERIAL CRUSHABILITY (FRENCH STANDARDS) : FROM 30%TO 55%
m/s 200 150 125 100 80 60 50 40 30 25 20 15
OC
CC
250520 660 x
1000x1600
1600OC 500 420 380 330 290 240*
36 CC 210 180 150
250520 480 x
800x 1280
800OC 530 440 400 345 305 250*
36 CC 225 195 160 140
250540 360 x
600x 960
350OC 570 480 440 380 330 280 245*
38 CC 210 170 150 130
250540 240 x
400x 640
100OC 490 430 380 315 280*
38 CC 240 200 170 145 120
200610 180 x
300x 480
45OC 455 395 330 290*
43 CC 250 210 185 160 130
200610 120 x
200x 320
12OC 420 350 315 270*
43 CC 225 200 170 140
200650 60 x
100x 160
1.6OC 300 250*
46 CC 220 190 160
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
MA
X. P
OW
ER
CH
RO
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IR
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SP
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CU
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Capacities - BP 1620
BP 1620
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING AT THE
FOLLOWING SQUARE OPENING (MM) :
kWrpm
mm kg
MATERIAL BULK DENSITY : 1.6MATERIAL CRUSHABILITY (FRENCH STANDARDS) : FROM 30%TO 55%
m/s 200 150 125 100 80 60 50 40 30 25 20 15
400420 780 x
1300x 2080
3000OC 740 635 570 460 425 350*
34 CC 310 265 220
400420 660 x
1000x1600
1600OC 825 700 630 550 480 400*
34 CC 345 300 250
400470 480 x
800x 1280
800OC 870 740 665 585 510 420*
38 CC 370 320 265 230
400470 360 x
600x 960
350OC 920 800 720 630 550 460 405*
38 CC 345 280 250 215
400470 240 x
400x 640
100OC 810 710 620 520 460*
38 CC 395 330 280 240 200
315530 180 x
300x 480
45OC 750 650 545 480*
43 CC 420 350 310 270 220
315530 120 x
200x 320
12OC 700 580 520 445*
43 CC 370 330 285 235
315530 60 x
100x 160
1.6OC 500 410*
43 CC 360 310 260
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
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Main characterisitics (HSI)
size 1007 1010 1013 1310 1313 1315 1620
FEED OPENING
Width (in.) 29 1/2 40 52 40 52 60 80 1/2
Height (in.) 25 1/2 28 30 1/2 39 1/2 45 45 55
ROTOR
Diameter (mm) 39 39 1/2 39 1/2 53 53 53 61
Number of hammers 4 4 4 4 4 4 5
POWER (hp) 75100125
125150200
150200250
150200250
200250300
250300350
350500
2 x 300
WEIGHT (lbs) 18300 22140 26400 34580 41490 48240 93710
Without feed box
HSI curves
HORIZONTAL SHAFT IMPACTORSAVERAGE OUTPUT CURVES
90% PRODUCT PASSING AT CORRESPONDING SQUARE OPENING
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in.)
Capacities - HSI 1007
HSI 1007
TOPFEED SIZE
BASIC CAPACITY (STPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING AT THE
FOLLOWING SQUARE OPENING (IN.) :
HPrpm
in. IbsMATERIAL BULK DENSITY : 1.6
fpm 6 5 4 3 2½ 2 1½ 11/4 1 3/4 1/2 3/8
OC
CC
125740 12 x
20x 32
440OC 195 175 155 130 110*
7480 CC 100 70 60 55 50
125740 10 x
16x 25
220OC 195 165 150 125 110*
7480 CC 95 80 65 60 45
125780 7 x
12x 19
100OC 180 160 130 115*
8070 CC 100 85 70 65 50 45
100780 5 x
8x 13
26OC 165 145 120 110*
8070 CC 90 85 70 55 50
100820 2 ½ x
4x 6½
3.5OC 125 105*
8465 CC 95 85 65 55
100880 1¼ x
2x 3¼
0.4OC 120 105*
9055 CC 95 70 60
OC
CC
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL PADDLE ABRASION INDEX :. .LESS THAN 0.0240 : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 0.0240 AND 0.2100 : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
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Capacities - HSI 1010
HSI 1010
TOPFEED SIZE
BASIC CAPACITY (STPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING AT THE
FOLLOWING SQUARE OPENING (IN.) :
HPrpm
in. IbsMATERIAL BULK DENSITY : 1.6
fpm 8 6 5 4 3 2½ 2 1½ 1¼ 1 3/4 1/2
OC
CC
OC
CC
200740 14 x
24x 38
770OC 265 240 210 180 155 140*
7480 CC 115 95 85 70
200740 10 x
16x 25
220OC 265 230 205 170 150*
7480 CC 125 105 95 85 55
150780 7 x
12x 19
100OC 250 220 180 160*
8070 CC 140 115 100 90 60
150780 5 x
8x 13
26OC 230 195 170 150*
8070 CC 120 110 95 65
150820 2½ x
4x 6½
3.5OC 165 140*
8465 CC 125 105 85
150880 1¼ x
2x 3¼
0.4OC 165 145*
9055 CC 120 100
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL PADDLE ABRASION INDEX :. .LESS THAN 0.0240 : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 0.0240 AND 0.2100 : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
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Capacities - HSI 1013
HSI 1013
TOPFEED SIZE
BASIC CAPACITY (STPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING AT THE
FOLLOWING SQUARE OPENING (IN.) :
HPrpm
in. IbsMATERIAL BULK DENSITY : 1.6
fpm 8 6 5 4 3 2½ 2 1½ 1¼ 1 3/4 1/2
OC
CC
OC
CC
250740 14 x
24x 38
770OC 515 435 400 340 293 255 220*
7480 CC 185 155 135 120
250740 10 x
16x 25
220OC 440 385 340 280 255*
7480 CC 215 180 155 135 90
200780 7 x
12x 19
100OC 415 355 295 260*
8070 CC 225 185 165 145 105
200820 5 x
8x 13
26OC 375 315 280 240*
8465 CC 200 180 155 110
200820 2½ x
4x 6½
3.5OC 265 225*
8465 CC 200 175 130
200880 1¼ x
2x 3¼
0.4OC 265 225*
9055 CC 185 155
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL PADDLE ABRASION INDEX :. .LESS THAN 0.0240 : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 0.0240 AND 0.2100 : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
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Capacities - HSI 1310
HSI 1310
TOPFEED SIZE
BASIC CAPACITY (STPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING AT THE
FOLLOWING SQUARE OPENING (IN.) :
HPrpm
in. IbsMATERIAL BULK DENSITY : 1.6
fpm 8 6 5 4 3 2½ 2 1½ 1¼ 1 3/4 1/2
OC
CC
250520 19 x
32x 50
1760OC 480 400 360 315 275 225*
7085 CC 200 175 145 125
250540 14 x
24x 38
770OC 515 435 400 340 295 255 220*
7480 CC 185 155 135 120
250540 10 x
16x 25
220OC 440 385 340 280 255*
7480 CC 215 180 155 135 90
200610 7 x
12x 19
100OC 415 355 295 260*
8465 CC 225 185 165 145 105
200610 5 x
8x 13
26OC 375 315 280 240*
8465 CC 200 180 155 110
200650 2½ x
4x 6½
3.5OC 265 225*
9055 CC 200 175 130
OC
CC
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL PADDLE ABRASION INDEX :. .LESS THAN 0.0240 : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 0.0240 AND 0.2100 : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
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Capacities - HSI 1313
HSI 1313
TOPFEED SIZE
BASIC CAPACITY (STPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING AT THE
FOLLOWING SQUARE OPENING ( IN.) :
HPrpm
in. IbsMATERIAL BULK DENSITY : 1.6
fpm 8 6 5 4 3 2½ 2 1½ 1¼ 1 3/4 1/2
300520 21 x
36x 57
2430OC 475 395 355 310 270 225*
7085 CC 200 170 140
300520 19 x
32x 50
1760OC 495 415 370 325 285 235*
7085 CC 210 180 155 130
300540 14 x
24x 38
770OC 535 465 410 360 315 265 230*
7480 CC 200 165 145 120
300540 10 x
16x 25
220OC 455 400 355 300 265*
7480 CC 225 185 160 140 95
200610 7 x
12x 19
100OC 425 370 310 275*
8465 CC 235 200 170 150 105
200610 5 x
8x 13
26OC 395 330 300 260*
8465 CC 215 185 160 115
200650 2½ x
4x 6½
3.5OC 280 235*
9055 CC 210 175 140
OC
CC
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL PADDLE ABRASION INDEX :. .LESS THAN 0.0240 : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 0.0240 AND 0.2100 : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
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Capacities - HSI 1315
HSI 1315
TOPFEED SIZE
BASIC CAPACITY (STPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING AT THE
FOLLOWING SQUARE OPENING (IN.) :
HPrpm
in. IbsMATERIAL BULK DENSITY : 1.6
fpm 8 6 5 4 3 2½ 2 1½ 1¼ 1 3/4 1/2
OC
CC
400520 24 x
40x 64
3530OC 620 520 470 410 360 300*
7085 CC 260 225 185
400520 19 x
32x 50
1760OC 657 545 495 430 380 310*
7085 CC 280 240 200 175
400540 14 x
24x 38
770OC 705 595 545 470 410 345 305*
7480 CC 260 210 185 160
400540 10 x
16x 25
220OC 605 535 470 390 345*
7480 CC 300 250 210 180 135
300610 7 x
12x 19
100OC 564 490 410 360*
8465 CC 310 260 230 200 140
300610 5 x
8x 13
26OC 520 435 390 335*
8465 CC 280 250 210 160
300650 2½ x
4x 6½
3.5OC 370 310*
9055 CC 275 235 185
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL PADDLE ABRASION INDEX :. .LESS THAN 0.0240 : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 0.0240 AND 0.2100 : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
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Capacities - HSI 1620
HSI 1620
TOPFEED SIZE
BASIC CAPACITY (STPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING AT THE
FOLLOWING SQUARE OPENING (IN.) :
HPrpm
in. IbsMATERIAL BULK DENSITY : 1.6
fpm 8 6 5 4 3 2½ 2 1½ 1¼ 1 3/4 1/2
600420 31 x
52x 83
6600OC 865 745 670 540 500 410*
6690 CC 365 310 260
600420 24 x
40x 64
3530OC 965 820 740 654 565 470*
6690 CC 405 350 295
600470 19 x
32x 50
1760OC 102 865 780 685 600 490*
7480 CC 435 375 310 270
600470 14 x
24x 38
770OC 108 940 845 740 645 540 475*
7480 CC 405 330 295 250
600470 10 x
16x 25
220OC 950 830 725 610 540*
7480 CC 465 385 330 280 215
450530 7 x
12x 19
100OC 880 760 640 565*
8465 CC 490 410 365 315 235
450530 5 x
8x 13
26OC 820 680 610 520*
8465 CC 435 385 335 245
450530 2½ x
4x 6½
3.5OC 585 480*
8465 CC 420 365 275
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCED OUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THE OUTPUTSREDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).. CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL PADDLE ABRASION INDEX :. .LESS THAN 0.0240 : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 0.0240 AND 0.2100 : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
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Estimation of hammer wear life (HSI)
ESTIMATION OF HAMMER WEAR LIFE (HOURS)
PRODUCT ABRASIVITY HAMMER MATERIALS
FRENCH STDABRG/T
US. STDPADDLE AI
G
MANGANESESTEEL
H
MARTENSITICSTEEL
H
CHROMEIRON
H
0 to 40 0 to 0.0020 more than 2000 More than 2400 More than 3000
40 to 100 0.0020 to 0.0050 1000 to 2000 1200 to 2400 More than 2000
100 to 150 0.0050 to 0.0100 400 to 1000 500 to 1200 1200 to 2000
150 to 250 0.0100 to 0.0240 150 to 400 200 to 500 800 to 1200
250 to 400 0.0240 to 0.0500 100 to 200 400 to 800
400 to 600 0.0500 to 0.1000 300 to 400
600 to 900 0.1000 to 0.2100 200 to 300
MORE THAN 900 MORE THAN 0.2100 APPLICATION FOR JAW OR CONE CRUSHER
Nordpactors
Flexibility................................................................................... 122Easy use and servicing ............................................................ 123Nordpactor curves .................................................................... 124NP 1620 capacities .................................................................. 125NP 1415 capacities .................................................................. 126NP 1313 capacities .................................................................. 127NP 1210 capacities .................................................................. 128Nordpactor SR curves .............................................................. 129NP 1520 SR capacities ............................................................ 130NP 1315 SR capacities ............................................................ 131NP 1213 SR capacities ............................................................ 132NP 1110 SR capacities ............................................................. 133NP 1007 SR capacities ............................................................ 134
Flexibility
A choice of primaries.
A choice of secondaries also adapted to the recycling.
A choice of different hammers qualities:
- Manganese steel
- Martensitic steel
- Cast iron
Possibility to have a 3rd braker plate in secondary machines.
Possibility of hydraulic assistance.
Possibility of hydraulic setting.
Same wear parts on an associated primary and secondary (complete plant).
The compact design enables a fitting on mobile equipment (portable or Lokotrack).
Easy use and servicing
- Inspection lateral and back doors.
- Hydraulic opening of the machine with a motorized pump.
- Beam and servicing pulley block.
- Dismantling of the hammers either sideways or upwards.
- Returning and refitting in place thanks to adapted tools supplied.
- More massive hammers then a less frequent changing.
- Profil of the hammer allowing its returning and then a maximum use of the wear part (rule 70/20/5/5).
- Locking of the hammers by wedges ensuring a perfect contact with the backing beam.
- Locking of the hammers allowing to push forwards the present limits of use of certainqualities of wear parts and then to have a less frequent change effect.
- Locking of the hammers very quickly limiting the down time and the loss of production as wellas the cost of manpower.
- Hydraulic assistance for the setting of the second breaker plate and the clearing of the firstbreaker plate (option on primary).
- Hydraulic setting of the primary and secondary breaker plates thanks to cylinders (option onthe secondaries).
- Side liners in anti-abrasion steel 400 HB (rule 70/20/5/5).
- Side liners are bolted on the frame and have a dimension allowing an heasy handling.
Nordpactor curves
NORDPACTOR H.S.I.AVERAGE OUTPUT CURVES FOR NP SERIES
90% PRODUCT PASSING AT CORRESPONDING SQUARE OPENING
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in)
NP 1620
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
MAXIMUM INSTALLED POWER : 400 KW
rpm mm kg
MATERIAL BULK DENSITY : 1.6 MATERIALCRUSHABILITY (FRENCH STANDARDS) : FROM 30% TO 55%
m/s 200 150 125 100 80 60 50 40 30 25 20 15
420 780X1300
X20803000
OC 760 660 580 480 420 350*
34 CC 310 260 220
420 600X1000
X16001600
OC 840 700 620 540 470 380*
34 CC 330 280 230
440 480X800
X1280800
OC 870 730 650 570 500 400*
36 CC 350 300 250 220
470 360X600
X960350
OC 930 780 710 620 530 430 380*
38 CC 330 260 230 210
470 240X400
X640100
OC 810 750 650 530 470*
38 CC 370 310 270 250 190
500 180X300
X48045
OC 870 760 620 540*
41 CC 450 370 330 280 230
500 120X200
X32012
OC 840 680 620 510*
41 CC 430 390 330 265
530 60X100
X1601,6
OC 570 480*
43 CC 420 360 300
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCEDOUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THEOUTPUTS REDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
NP 1620 capacities
MA
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NP 1415
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
MAXIMUM INSTALLED POWER : 250 KW
rpm mm kg
MATERIAL BULK DENSITY : 1.6 MATERIALCRUSHABILITY (FRENCH STANDARDS) : FROM 30% TO 55%
m/s 200 150 125 100 80 60 50 40 30 25 20 15
495 600X1000
X16001600
OC 540 450 400 350 300 240*
35 CC 210 180 150
520 480X800
X1280800
OC 560 470 420 365 315 250*
36 CC 225 195 160 140
520 360X600
X960350
OC 600 500 460 400 340 280 245*
36 CC 210 170 150 135
550 240X400
X640100
OC 520 480 420 340 300*
39 CC 240 200 175 150 130
585 180X300
X48045
OC 560 490 400 350*
42 CC 290 240 210 180 150
585 120X200
X32012
OC 540 440 400 330*
42 CC 280 250 210 170
615 60X100
X1601,6
OC 370 310*
44 CC 270 230 190
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCEDOUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THEOUTPUTS REDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
MA
X. P
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ER
CH
RO
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ON
CIR
CU
IT
NP 1415 capacities
NP 1313 capacities
NP 1313
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
MAXIMUM INSTALLED POWER : 200 KW
rpm mm kg
MATERIAL BULK DENSITY : 1.6 MATERIALCRUSHABILITY (FRENCH STANDARDS) : FROM 30% TO 55%
m/s 200 150 125 100 80 60 50 40 30 25 20 15
520 540X900
X14401100
OC 430 360 320 280 240 190*
35 CC 170 145 115
520 480X800
X1280800
OC 450 375 335 290 250 200*
35 CC 180 155 125 110
550 360X600
X960350
OC 480 400 370 320 270 220 190*
37 CC 170 135 120 110
550 240X400
X640100
OC 415 380 330 270 240*
37 CC 330 260 230 210
620 180X300
X48045
OC 450 390 320 280*
42 CC 230 190 170 145 120
620 120X200
X32012
OC 430 350 320 260*
42 CC 220 200 165 135
660 60X100
X1601,6
OC 300 250*
45 CC 210 180 150
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCEDOUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THEOUTPUTS REDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
MA
X. P
OW
ER
CH
RO
ME
IR
ON
CIR
CU
IT
NP 1210 capacities
NP 1210
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
MAXIMUM INSTALLED POWER : 160 KW
rpm mm kg
MATERIAL BULK DENSITY : 1.6 MATERIALCRUSHABILITY (FRENCH STANDARDS) : FROM 30% TO 55%
m/s 200 150 125 100 80 60 50 40 30 25 20 15
OC
CC
560 480X800
X1280800
OC 330 280 250 220 190 150*
35 CC 135 120 100 85
580 360X600
X960350
OC 360 300 280 240 200 170 150*
37 CC 125 105 90 80
580 240X400
X640100
OC 310 290 250 200 180*
37 CC 145 120 105 90 80
650 180X300
X48045
OC 330 290 240 210*
41 CC 170 140 125 110 90
650 120X200
X32012
OC 320 260 240 200*
41 CC 165 145 120 100
700 60X100
X1601,6
OC 220 180*
44 CC 160 140 110
OC
CC
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCEDOUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THEOUTPUTS REDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
MA
X. P
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ON
CIR
CU
IT
NORDPACTOR H.S.I.AVERAGE OUTPUT CURVES FOR NP SR SERIES
90% PRODUCT PASSING AT CORRESPONDING SQUARE OPENING
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in)
Nordpactor SR curves
NP 1520 SR capacities
NP 1520 SR
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
MAXIMUM INSTALLED POWER : 400 KW
rpm mm kg
MATERIAL BULK DENSITY : 1.6 MATERIALCRUSHABILITY (FRENCH STANDARDS) : FROM 30% TO 55%
m/s 200 150 125 100 80 60 50 40 30 25 20 15
480 360X700
X960500
OC 800 720 660 570 500 450 370*
37 CC 320 270 250 220
500 240X400
X640100
OC 780 690 600 500 450*
39 CC 400 340 300 260 230
530 180X300
X48045
OC 800 720 600 540 460*
42 CC 410 370 320 270
560 120X200
X32012
OC 830 690 640 560 470*
44 CC 420 360 300
580 60X100
X1601,6
OC 600 510*
46 CC 450 380 330
630 30X50
X800,2
OC 500*
49 CC 400 350
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCEDOUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THEOUTPUTS REDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
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NP 1315 SR capacities
NP 1315 SR
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
MAXIMUM INSTALLED POWER : 250 KW
rpm mm kg
MATERIAL BULK DENSITY : 1.6 MATERIALCRUSHABILITY (FRENCH STANDARDS) : FROM 30% TO 55%
m/s 150 125 100 80 60 50 40 30 25 20 15
550 360X600
X960350
OC 480 440 380 330 280 245*
37 CC 220 180 165 145
585 240X400
X640100
OC 490 430 380 315 280*
40 CC 250 210 185 165 145
615 180X300
X48045
OC 500 450 380 340 290*
42 CC 260 230 200 170
660 120X200
X32012
OC 520 430 400 350 300*
45 CC 265 225 190
700 60X100
X1601,6
OC 380 320 280*
48 CC 240 210
700 30X50
X800,2
OC 310 250*
48 CC 220
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCEDOUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THEOUTPUTS REDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
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NP 1213 SR capacities
NP 1213 SR
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
MAXIMUM INSTALLED POWER : 200 KW
rpm mm kg
MATERIAL BULK DENSITY : 1.6 MATERIALCRUSHABILITY (FRENCH STANDARDS) : FROM 30% TO 55%
m/s 150 125 100 80 60 50 40 30 25 20 15
580 360X600
X960350
OC 380 350 300 260 220 190*
37 CC 170 140 130 110
610 240X400
X640100
OC 390 340 300 250 220*
39 CC 200 170 150 130 110
660 180X300
X48045
OC 400 360 300 270 230*
41 CC 210 180 160 130
700 120X200
X32012
OC 410 350 320 280 230*
44 CC 200 180 150
740 60X100
X1601,6
OC 300 250 220*
46 CC 190 160
780 30X50
X800,2
OC 300 250 200*
49 CC 170
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCEDOUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THEOUTPUTS REDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
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NP 1110 SR
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
MAXIMUM INSTALLED POWER : 160 KW
rpm mm kg
MATERIAL BULK DENSITY : 1.6 MATERIALCRUSHABILITY (FRENCH STANDARDS) : FROM 30% TO 55%
m/s 150 125 100 80 60 50 40 30 25 20 15
620 360X600
X960350
OC 290 260 230 200 170 150*
36 CC 130 110 100 85
660 240X400
X640100
OC 300 260 230 190 170*
38 CC 150 125 110 100 85
700 180X300
X48045
OC 300 270 230 200 175*
40 CC 155 140 120 100
740 120X200
X32012
OC 310 260 240 210 180*
43 CC 155 130 110
780 60X100
X1601,6
OC 230 190 170*
45 CC 140 120
830 30X50
X800,2
OC 200 185 150*
48 CC 130
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCEDOUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THEOUTPUTS REDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
NP 1110 SR capacities
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NP 1007 SR capacities
NP 1007 SR
TOPFEED SIZE
BASIC CAPACITY (MTPH) OF CRUSHEDMATERIAL WITH 90% PRODUCT PASSING ATTHE FOLLOWING SQUARE OPENING (MM) :
MAXIMUM INSTALLED POWER : 90 KW
rpm mm kg
MATERIAL BULK DENSITY : 1.6 MATERIALCRUSHABILITY (FRENCH STANDARDS) : FROM 30% TO 55%
m/s 150 125 100 80 60 50 40 30 25 20 15 10
705 300X500
X800200
OC 175 160 140 120 100 90*
37 CC 80 65 60 50
790 240X400
X640100
OC 175 150 135 115 100*
37 CC 90 75 65 60 50
790 180X300
X48045
OC 180 160 135 120 105*
41 CC 90 80 70 60 45
835 120X200
X32012
OC 190 155 145 125 105*
44 CC 90 80 70 55
835 60X100
X1601,6
OC 135 115 100*
44 CC 85 75 60
940 30X50
X800,2
OC 130 110 90*
49 CC 80 65
- ABOVE BASIC CAPACITIES ARE OBTAINED WITH CORRESPONDING MAXIMUM POWER.
- FOR REDUCEDOUTPUTS, THE NECESSARY POWER IS PROPORTIONAL TO THEOUTPUTS REDUCTION.
- * . LIMIT OF CAPACITY AND GRADATION IN OPEN CIRCUIT (OC).CORRESPONDING CURVE TO BE USED FOR CLOSED CIRCUIT (CC) APPLICATIONS.
- ACCORDING TO MATERIAL CRUSHABILITY (FRENCH STANDARDS) :. BETWEEN 20% AND 30% : BASIC CAPACITY x 0.85. BETWEEN 55% AND 75% : BASIC CAPACITY x 1.15. LESS THAN 20% OR MORE THAN 75% : CONSULT MACHINES DEPARTMENT.
- ACCORDING TO MATERIAL ABRASIVITY (FRENCH STANDARDS) :. LESS THAN 250 G/T : USE OF MANGANESE STEEL HAMMERS.. BETWEEN 250 AND 900 G/T : POSSIBILITY TO USE CHROME IRON HAMMERS FOR ABOVEAPPLICATIONS MARKED WITH
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Recycling
Nordberg Impact Crushers guidelinesin recycling applications ........................................................... 136Impactors curves : Output in demolition rubbleand concrete (production of minus 70 mm) ............................. 138Impactors curves : Output in demolition rubbleand concrete (production of minus 40 mm) ............................. 139Performances (mm) : Output in demolition rubbleand concrete ............................................................................ 140Performances (in.) : Output in demolition rubbleand concrete ............................................................................ 141Impactors curves : output in asphalt recycling(production of minus 40 mm) ................................................... 142Impactors curves : output in asphalt recycling(production of minus 20 mm) ................................................... 143Performances (mm) : Output in asphalt ................................... 144Performances (in.) : Output in asphalt ..................................... 145Citycrusher 1007 ...................................................................... 146Citycrusher curves : Output in demolition rubbleand concrete (production of minus 40 mm) ............................. 147Citycrusher curves : Output in demolition rubbleand concrete (production of minus 70 mm) ............................. 148Citycrusher curves : Output in asphalt recycling(production of minus 20 mm) ................................................... 149Citycrusher curves : Output in asphalt recycling(production of minus 40 mm) ................................................... 150Impact crusher BP 1010 curves ............................................... 151Impact crusher BP 1013 curves ............................................... 152
Nordberg Impact Crushers guidelines in recycling applications
RAW MATERIALS TO BE PROCESSED
3 main qualities:
Concrete with or without rebars:
They can be defined according to their components:
- Aggregates which are fine or coarse, which are abrasive or not ...- The cement content.- The density and the thickness of the re-bars.
Demolition materials:
Normally composed of very heterogen materials: concrete, bricks, wood, steel, several rocksquality.
Asphalts:
They can be defined according to their components:
- Aggregates more or less abrasive.- Tar content.
ADVANTAGES OF IMPACT CRUSHER IN RECYCLING
- High reduction ratio.
- Efficient way to separate the re-bars from aggregates in reinforced concrete.
- Excellent shape coefficient of end products.
- Possibility to run in closed circuit.
- Cheaper capital investment than Jaw-cone solution.
FEED PREPARATION
To achieve a good preparation of the feed materials :
- Sorting of uncrushable materials: metallic pieces, wood sleepers.
- Feed materials: size of the concrete slabs, concrete blocks or asphalt material should beadapted to the size of the impact crusher.
- Closed circuit arrangement: to find a way to take away the metallic parts returning to thecrusher.
QUALITIES OF HAMMERS
Manganese steel:
The only quality enabling to crush without breakage.
Martensitic steel:
With some risks of breakages according to the materials processed and the reductionrequested.Resists better to the wear than manganese.
Chromium cast iron:
Good for asphalt processing if there is no tramp iron.High risks of breakages in concrete and demolition but the financial balance can be positive ifthe customer is aware of such risks and accepts them.
HAMMER LIFE
Considering the heterogeneity of the different feeds the lifes forecasts are difficult and approxi-mative.
As rule of thumb, we can keep in mind the following values:
- Manganese steel hammers:Concrete : 50 to 100 hoursDemolition : 40 to 200 hoursAsphalt : 40 to 150 hours
- Martensitic steel hammers:1.2 to 1.5 times the values for Mn
- Chromium cast iron:3 to 4 times the values for Mn
PRODUCTION
Refer to the attached specific production charts for recycling.
PRODUCTION CURVES
The production curves are very fluctuating and follow the fluctuation of the feed curves.
Refer to the general shape of the attached curves obtained from actual site where actualrecycling was performed.
Impactors curves : Output in demolition rubble and concrete (production of minus 70mm
HS IMPACTORSOUTPUT IN DEMOLITION RUBBLE AND CONCRETE
PRODUCTION OF MINUS 70 MMOUTPUT GRADATION ENVELOPE
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in)
0.065 0.13 0.25 0.5 1 2 3
Impactors curves : Output in demolition rubble and concrete (production of minus 40mm
HS IMPACTORSOUTPUT IN DEMOLITION RUBBLE AND CONCRETE
PRODUCTION OF MINUS 40 MMGRADATION CURVES : OUTPUT ENVELOPE
SITE RESULTS
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in)
0.065 0.13 0.25 0.5 1 2 3
OUTPUT IN DEMOLITION RUBBLE AND CONCRETE
SIZEPOWER SPEED TOP FEED SIZE
BASIC CAPACITY (MTPH) OFCRUSHED MATERIAL WITH 90 %
PRODUCT PASSING AT THEFOLLOWING SQUARE OPENING
(MM)
kW RPM / M/S MM 120 70 40
1007 75 610 / 32300 x 500 x 800 110 80 50
150 x 250 x 400 130 100 65
1010 90 610 / 32350 x 600 x 900 150 110 75
180 x 300 x 450 190 130 85
1013 110 610 / 32350 x 600 x 1000 180 130 90
180 x 300 x 500 230 170 110
1310 132 450 / 32500 x 800 x 1200 180 130 90
250 x 400 x 600 230 170 120
1313 160 450 / 32520 x 900 x 1400 210 160 110
260 x 450 x 700 270 200 140
1315 200 450 / 32600 x 1000 x 1600 250 190 140
300 x 500 x 800 300 230 170
Performances depend on preparation of the feed material.Above basic capacities are obtained with corresponding power ; for reduced outputs the necessary poweris proportional to the outputs reduction.
Performances (mm) : Output in demolition rubble and concrete
OUTPUT IN DEMOLITION RUBBLE AND CONCRETE
SIZEPOWER SPEED TOP FEED SIZE
BASIC CAPACITY (MTPH) OFCRUSHED MATERIAL WITH 90 %
PRODUCT PASSING AT THEFOLLOWING SQUARE OPENING
(IN)
HP RPM / FPM IN. 5 3 1.5
1007 100 610 / 630012 x 20 x 32 120 90 55
6 x 10 x 16 145 110 70
1010 120 610 / 630014 x 24 x 36 160 120 80
7 x 12 x 18 210 150 95
1013 150 610 / 630014 x 24 x 40 200 145 100
7 x 12 x 20 250 190 120
1310 200 450 / 630019 x 32 x 50 220 175 120
9 1/2 x 16 x 25 270 200 140
1313 250 450 / 630021 x 36 x 57 240 185 130
10 1/2 x 18 x 23 1/2 310 230 160
1315 300 450 / 630024 x 40 x 64 280 210 160
12 x 20 x 32 350 260 180
Performances depend on preparation of the feed material.Above basic capacities are obtained with corresponding power ; for reduced outputs the necessary poweris proportional to the outputs reduction.
Performances (in.) : Output in demolition rubble and concrete
Impactors curves : output in asphalt recycling (production of minus 40 mm)
HS IMPACTORSOUTPUT IN ASPHALT RECYCLING
PRODUCTION OF MINUS 40 MMOUTPUT GRADATION ENVELOPE
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in)
0.065 0.13 0.25 0.5 1 2 3
Impactors curves : output in asphalt recycling (production of minus 20 mm)
HS IMPACTORSOUTPUT IN ASPHALT RECYCLING
PRODUCTION OF MINUS 20 MMOUTPUT GRADATION ENVELOPE
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in)
0.065 0.13 0.25 0.5 1 2 3
OUTPUT IN ASPHALT
SIZEPOWER SPEED TOP FEED SIZE
BASIC CAPACITY (MTPH) OFCRUSHED MATERIAL WITH 90 %
PRODUCT PASSING AT THEFOLLOWING SQUARE OPENING
(MM)
kW RPM / M/S MM 70 40 20
1007 75 540 / 28 300 x 500 x 700 80 65 50
1010 90 540 / 28 300 x 600 x 800 110 90 60
1013 110 540 / 28 300 x 650 x 900 130 110 70
1310 132 400 / 28 400 x 800 x 1000 140 120 85
1313 160 400 / 28 500 x 900 x 1100 180 150 115
1315 200 400 / 28 500 x 1000 x 1300 210 180 135
Performances depend on preparation of the feed material.Above basic capacities are obtained with corresponding power ; for reduced outputs the necessary poweris proportional to the outputs reduction.
Performances (mm) : Output in asphalt
OUTPUT IN ASPHALT
SIZEPOWER SPEED TOP FEED SIZE
BASIC CAPACITY (MTPH) OFCRUSHED MATERIAL WITH 90 %
PRODUCT PASSING AT THEFOLLOWING SQUARE OPENING
(IN)
HP RPM / FPM IN. 3 1.5 3/4
1007 100 540 / 5510 12 x 20 x28 90 70 50
1010 120 540 / 5510 14 x 2 x 36 120 95 60
1013 150 540 / 5510 16 x 32 x 40 145 120 70
1310 200 400 / 5510 19 x 32 x 50 170 140 95
1313 250 400 / 5510 20 x 36 x 44 210 160 120
1315 300 400 / 5510 20 x 40 x 52 240 180 145
Performances depend on preparation of the feed material.Above basic capacities are obtained with corresponding power ; for reduced outputs the necessary poweris proportional to the outputs reduction.
Performances (in.) : Output in asphalt
Citycrusher 1007
Citycrusher curves : Output in demolition rubble and concrete (production of minus 40mm)
CITYCRUSHER 1007OUTPUT IN DEMOLITION RUBBLE AND CONCRETE
PRODUCTION OF MINUS 40 MMCAPACITY : 40 TO 90 MTPH (45 TO 100 STPH)GRADATION CURVES : OUTPUT ENVELOPE
SITE RESULTS
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in)
0.065 0.13 0.25 0.5 1 2 3
PERFORMANCES DEPEND ON PREPARATION AND PRECRUSHING OF THE FEED MATERIAL
Citycrusher curves : Output in demolition rubble and concrete (production of minus 70mm)
CITYCRUSHER 1007OUTPUT IN DEMOLITION RUBBLE AND CONCRETE
PRODUCTION OF MINUS 70 MMCAPACITY : 55 TO 125 MTPH (60 TO 135 STPH)
OUTPUT GRADATION ENVELOPE
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in)
0.065 0.13 0.25 0.5 1 2 3
PERFORMANCES DEPEND ON PREPARATION AND PRECRUSHING OF THE FEED MATERIAL
Citycrusher curves : Output in asphalt recycling (production of minus 20 mm)
CITYCRUSHER 1007OUTPUT IN ASPHALT RECYCLING
PRODUCTION OF MINUS 20 MMCAPACITY : 45 TO 85 MTPH (50 TO 95 STPH)
OUTPUT GRADATION ENVELOPE:
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in)
0.065 0.13 0.25 0.5 1 2 3
PERFORMANCES DEPEND ON PREPARATION AND PRECRUSHING OF THE FEED MATERIAL
Citycrusher curves : Output in asphalt recycling (production of minus 40 mm)
CITYCRUSHER 1007OUTPUT IN ASPHALT RECYCLING
PRODUCTION OF MINUS 40 MMCAPACITY : 55 TO 105 MTPH (60 TO 115 STPH)
OUTPUT GRADATION ENVELOPE:
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in)
0.065 0.13 0.25 0.5 1 2 3
PERFORMANCES DEPEND ON PREPARATION AND PRECRUSHING OF THE FEED MATERIAL
Impact crusher BP 1010 curves
IMPACT CRUSHER BP 1010
PRODUCTION OF MINUS 40 MMCAPACITY : 75 TO 130 MTPH (80 TO 145 STPH)
OUTPUT GRADATION ENVELOPE:
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in)
0.065 0.13 0.25 0.5 1 2 3
PERFORMANCES DEPEND ON PREPARATION AND PRECRUSHING OF THE FEED MATERIAL
Impact crusher BP 1013 curves
IMPACT CRUSHER BP 1013
PRODUCTION OF MINUS 40 MMCAPACITY : 105 TO 175 MTPH (115 TO 190 STPH)
OUTPUT GRADATION ENVELOPE:
% CUMULATIVE PASSING AT SQUARE OPENING SIEVES
SQUARE OPENING SIEVES (mm)
SQUARE OPENING SIEVES (in)
0.065 0.13 0.25 0.5 1 2 3
PERFORMANCES DEPEND ON PREPARATION AND PRECRUSHING OF THE FEED MATERIAL
Specifications .............................................................................. 154Technical description................................................................... 155Production ................................................................................... 156
Cityscreen 1030
Specifications
Transportation dimensions
Overall length : 8,270 mWidth : 2,50 mHeight : 2,890 mWeight : 11500 kg
Vibrating screenLength : 3 mWidth : 1 mScreening area : 3 m2
Number of decks : 2
Citycrusher 1007 Cityscreen 1030
Technical description
. CVB 1030/II vibrating screen driven by 5.5 kW squirrel cage motor.
. Feed conveyor to the screen, 500 mm x 6 m driven by 4 kW squirrel cage motor withgear reducer.
. Lower deck product conveyor 500 mm x 4.8 m driven by 4 kW squirrel cage motor withgear reducer.
. Stockpiling conveyor for final product, 500 mm x 3 m driven by 4 kW squirrel cagemotor with a gear reducer.
. Top deck oversize product chute.
. Main control panel with protection devices and interconnecting cabling ready fitted.
. Hydraulik system for lifting screen and conveyors into working position.
. Rolled steel chassis equipped for hydraulik hook loading system.
Production
Working with a Citycrusher 1007, the Cityscreen 1030 has a typical output performance inasphalt/concrete material of:
23 tph of 0/1010 tph of 10/2017 tph of +20
Sand impactor BP 10.05
1
2 34 5
6 7
8
Technical informations.............................................................. 158Typical screen granulametric curves (for information) ............. 159
Technical description
1 The selection of large double row rolling element bearings permits high rotor speed.
2 Abrasion resistant blow bars and liner plates are selected to suit the feed material.
3 Easily locked blow bars are reversible to maintain the balance of the rotor and give maximumlife.
4 Replaceable rotor protection plates.
5 Adjustable heads ensure perfect balancing of the two blow bars.
6 Breaker plate fitted with protective shock absorbers.
7 The crushing chamber is fitted with liners designed to ensure correct internal distribution of thefeed.
8 Safety devices fitted for use during maintenance periods.
Characteristics
Inlet cross section mm 520 x 215 Maximum feed size
Rotor diameter mm 1000 Non-abrasive material mm 80
Total weight kg 3850 Abrasive material mm 60
Installed power kW 110 Approximate capacity t/h 60
Feed height mm 1750
Technical informations
Typical screen granulametric curves (for information)
SQUARE OPENING
Hammer mill BM 100.125
Tecnical informations................................................................ 161
56 43
12 7
Technical description
1 Large spherical roller bearings sized for long life and possible evolution of the rotation speed.
2 Main frame provided with a trap to capture possible tramp iron.
3 Hardened steel hammers axles.
4 Three positions for fixation on the rotor and symetrical design of the hammers allow wear com-pensation and optimisation.
5 Manganese liner plates for main crushing areas and abrasion resistant liners elsewhere.
6 Calibrating bars and/or grids made of manganese steel are locked by a simple device.
7 Safety device for frame opening.
Characteristics
Inlet cross section mm 1200 x 490 Maximum feed size mm 250
Rotor diameter mm 1000 Approximate capacity t/h 30 of 0/2 mm (CC)
Total weight kg 9520 at 132 kW 40 of 0/4 mm (OC)
Installed power kW 110 to 160 (CC) : closed circuit 55 of 0/6 mm (OC)
(OC) : open circuit 80 of 0/10 mm (OC)
Tecnical informations
1 32
4
5 6
47
Vertical shaft impactor VI 16.65
Technical characteristics .......................................................... 163
Technical characteristics
1 The selection of shaft bearings permits possible evolution of the rotation speed.
2 Automatic grease lubrication to get long life of the shaft bearings.
3 Standard equipment for processing abrasive material : rock box design rotor with discharge tipsand rock box anvil. In case of less abrasive material, the VI can be equiped with shoe rotor andanvil ring.
4 Rotor and top cover liners made of chrome iron and wear resistant steel. Shell and main shaftbox are protected by rubber curtains.
5 Easy monitoring and maintenance by two inspection doors located on the top cover.
6 Adjustable position of the feed tube.
7 A vibration detector device shuts down automatically the machine in case of considerablevibrations.
Screens
The range of screens ............................................................... 165Secondary CVB screens .......................................................... 167ELLIVAR screens .................................................................... 168CVBD screens.......................................................................... 169V-screens ................................................................................. 170Capacities................................................................................. 171Capacities of sizing screens .................................................... 172Primary CVB screens ............................................................... 173Capacities of primary CVB screens ......................................... 176CSB scalping screens .............................................................. 177EDB scalping screens .............................................................. 178Scalping information................................................................. 179Capacities of scalping screens ................................................ 182ATV Feeders: ATV 09-40 - ATV 11-50 - ATV 14-65 ................. 183ATV Feeders: ATV 06-23 - ATV 08-35 - ATV 11-45 ................. 184Capacities of ATV Feeders ...................................................... 185Choice of a screen ................................................................... 186
The range of screens
MACHINE CVB 1020 CVB 1030 CVB 1330 CVB 1540 CVB 1845
Size :
widthh mm 1000 1000 1300 1500 1800
length mm 2000 3000 3000 4000 4500
Screening surface m2 2 3 4 6 8
Number of decks possible II III IV II III IV II III IV II III IV II III IV
Angle of operation 18° 18° 18° 18° 18°
Motor :
Electric
Short-circuit rotor
1500 REVSper/mn
Power :
II or II 1/2 decks kW 4 5.5 5.5 11 15
IIII decks kW 4 5.5 5.5 11 22
IV decks kW 4 5.5 7.5 15 22
Rotationspeed min REVS per/mn 800 800 800 800 800
of screen max. REVS per/mn 1100 1100 1100 1000 1000
Amplitude mm 5 to 10 5 to 10 5 to 10 6 to 10 6 to 10
Drive :
V-belts
number and type 3 - 17 x 11 4 - 17 x 11 4 - 17 x 11 4 - SPB 5 -SPB
belt length mm 1330 1720 1720 2340 2430
Lubricating system (oil splash)
Weight of complete screen :
II decks kg 1400 2390 2560 4100 5500
II 1/2 decks kg - - - - -
III decks kg 1650 2720 2940 4800 6800
IV decks kg 1900 3100 3360 5560 7800
Maximum lift tonnes 1 1 1 1 2
Rinsing capacity (see water sprays)
Primary screen (II decks) yes - yes yes -
MACHINECVB2050
CVB2060
ELLIV13
ELLIV16
ELLIV20
ELLIV25
ELLIV30
CVDB1550
CVDB1850
Size :
widthh mm 2000 2000 2200 2630 2630 3300 3300 1500 1800
length mm 5000 6000 6100 6100 7625 7625 9150 5000 5000
Screening surface m2 10 12 13 16 20 25 30 7.5 9
Number of decks possibleII III II III IV I II ½
III IVII II ½
IIIII II ½
IIIII III II II III II III
Angle of operation 18° 18° 20° 20° 15° 15° 15° 0° 0°
Motor :
Electric
Short-circuit rotor
1500 REVSper/min
Power :
II or II 1/2 decks kW 22 22 2 x 11 2 x 15 2 x 15 2 x 22 2 x 30 2 x 11 2 x 11
IIII decks kW 22 22 2 x 11 2 x 15 2x18.5 2 x 22 - 2 x 11 2 x 11
IV decks kW 22 22 2 x 11 - - - - - -
Rotationspeed min REVS per/mn 800 800 900 900 900 900 900 800 800
of screen max. REVS per/mn 1000 1000 1100 1100 1100 1100 1100 1000 1000
Amplitude mm 6 to 10 6 to 10 4 to 10 4 to 10 4 to 10 6to10.5 6 to 9.5 6 to 14 6 to14
Drive :
V-belts
number and type 5 SPB 5 SPB2 x 3SPB
2 x 4SPB
2x3-152 x 5SPB
2 x 5SPB
2 x 3SPB
2 x 3SPB
belt length mm 2650 2650 3650 3650 4750 2120 - 1750 1750
Lubricating system • • • • • • • • •
Weight of complete screen :
II decks kg 6200 7500 10400 13600 15300 21500 23500 5000 6200
II 1/2 decks kg - - 11100 15600 17000 - - - -
III decks kg 7500 9300 12300 17000 19300 25000 - 6300 7000
IV decks kg 8800 10800 15000 - - - - - -
Maximum lift tonnes 2 2 2 2 2 2 2 2.5 2.5
Rinsing capacity (see water sprays)
Primary screen (II decks) yes - - - - - - - -
Secondary CVB screens
Presentation
Description
. Mechanism: one cylindrical shaft mounted with 2 (sphericall rollers) bearings.Counterweights are outside the sideplates.
. Circular vibration
. Side-tensioned decks
. The drive can be either on right hand or left hand.
SCREENCLOTHS
RUBBERCOVERS
FEED BOX
BELTS
MECHANISM
GUARDS
CHECK
SUSPENSIONSPRINGS
MOTORSUPPORT
PULLEYSSUSPENSIONSPRINGS
ELLIVAR screens
Presentation
Description
. Mechanism: 2 vibrating units at the top of the vibrating body.2 (cylindrical rollers) bearings per vibrating units.
. Elliptic vibration.
. Side-tensioned decks with central tension hook.
. One drive per vibrating units.
SUSPENSIONSPRINGS
EXCITERS
SUPPORTINGBASES
BELT
RUBBER SHOCKABSORBER
CVBD screens
Presentation
Description
. Mechanism: 2 shafts mounted with 4 (spherical rollers) bearings.no gear: self synchronized
. Linear vibration inclined at 45°
. Side-tensioned decks
. Drive: 1 motor per shaft-line.motors are mounted on the vibrating body.
V-screens
Description
. Vertical drum which rotates and vibrates (centrifugal force).
. Only one split.
Application
. Fine meshes (up to 8 mm) with maximum feed size of 20 mm.
Options
. Dust extraction.
. Fillers removing.
Calculation
. According to the feed graduation, NORDBERG can make your calculation.
Capacities
See table.
Datas have been determinated depending on:- Information we have got from the sites.- Stenght of the deck support frames.- Acceleration capability of the mechanism.
Data will be updated depending on new informations and changes.
Important
- These capacities are not the only parameters of selection:the area calculation is also determinative.
- These capacities can be increased by the amount of thehalf-size passing at the bottom deck which does not load the screen.
0-30= 120 t/h
0-10= 50 t/h
Example
Area calculation gives : CVB 1540 II
Check-up with the table : maximum total feed capacity = 350 t/hSo, 380 > 350 => CVB 1540 II is not
suitable
But : lower deck (split at 20) : half-size = 50 t/h
=>Actual maximum total feed capacity is :350 + 50 = 400 t/h => CVB 1540 II is suitable
220
80
160
80
Split at 60
Split at 20
380 t/h
Capacities of sizing screens
CAPACITIES OF SIZING SCREENS
MAXIMUM TOTAL FEED CAPACITY (T/h) Maximumfeed size
(mm)
Maximumsplit (mm)
NUMBER OF DECKS * 1 2 2 ½ 3 3 ½ 4
CVB 1020 70 100 90 80
CVB 1030 140 200 180 160 1
CVB 1330 140 200 180 160
CVB 1540 250 350 325 300 150 à
CVB 1845 300 500 450 400
CVB 2050 350 500 450 400 100
CVB 2060 350 500 550 500
ELLIVAR 13 420 600 575 550 525 500
ELLIVAR 16 500 700 650 600 550
ELLIVAR 20 500 700 650 600 120 1 à 50
ELLIVAR 25 700 1000 900 800
ELLIVAR 30 700 1000 900
CVDB 1550 280 400 350 120 1 à 50
CVDB 1850 280 400 350
"V" SCREEN 80 25 0.5 à 6
* Maximum oversize tonnage on a single deck (rinsing for instance).
IMPORTANT :These capacities are not the only parameters of selection : the area calculation is also determinative.These capacities can be increased by the amount of the half-size passing at the bottom deck that do notload the screen.
Primary CVB screens
This range is issued of the standard CVB range.
Presentation
Differences from sizing CVB screen
- 1st deck designed to be fitted with bolted screening pannelsStandard : perforated steel plates (tensile strenght = 36
daN/mm2)Options :. perforated steel plates (type HARDOX400). perforated rubber pannels
- Other decks are common with the sizing CVB screens : wire woven cloths side-tensioned.
- In some cases, the mechanism is stronger (compared to standard CVB) because of theheavier vibrating body.
- Rubber liner for the shaft housing.
- In some cases the suspension is reinforced (more springs).
- Higher side plates : to prevent escaped material.
- Wear steelplates are bolted inside the sideplates (on 1st deck only).
- No feedbox.
- The settings are adapted to primary screening=> larger stroke, lower rotation speed (prevent plugging)
Application
Primary CVB are required when :
- Feedsize is more than 150 mm- Feed capacity is big.
Important
Area calculation of 1st deck must take into account the perforated plates free area (See chapter 51).
Capacities
See table.The data have been determinated depending on :
- Information we have got from sites.- Strenght of the deck support frames.- Acceleration capability of the mechanism.
Important
- These capacities are not the only parameters of selection: the area calculation is alsodeterminative.
- These capacities can be increased by the amount of the half-size passing at the bottomdeck which does not load the screen.
Example
0-75= 245 t/h
0-40= 135 t/h
0-20= 120 t/h
Area calculation gives CVB 2060 IIIP
Check-up with table : maximum total feed capacity =600 t/hSo 700 > 600 => CVB 2060 IIIPis not suitable
But : lower deck (split at 50) : half-size = 120 t/h
=>Actual maximum total feed capacity is :600 + 120 = 720 t/h => CVB 2060 IIIP is suitable
350
90
100
350
260
160
Split at 150
Split at 80
Split at 50
700 t/h
Capacities of primary CVB screens
(1) These capacities can be increased by the amount of the half-size at the bottom deck that do notload the screen.
(2) This amplitude is combined with a 800 RPM speed in order to keep a correct bearings life.
CAPACITIES OF PRIMARY SCREENS
MACHINEMax. total
feed capacity(T/H) (1)
Max.oversize
capacity onthe top deck
Max.feed size
mm
Max. weightof the blocks
(kg)
Max. feedheight
(m)
Max. spliton 1st
deck (mm)
Max.amplitude(mm) (2)
CVB 1020 II P 120 70 250 30 9
CVB 1330 II P 230 140 250 30 120 10
CVB 1540 II P 450 250 400 100 10
CVB 1845 II P 550 300 400 100 0.3 13
CVB 1845 III P 450 300 400 100 12
CVB 2050 II P 600 350 400 100 150 12
CVB 2050 III P 500 350 400 100 11
CVB 2060 II P 700 450 400 100 12
CVB 2060 III P 800 450 400 100 11
CSB scalping screens
Presentation
Description
. Mechanism : one cylindrical shaft mounted with 2 spherical rollers bearings.counterweights are outside the sideplates.
. Circular vibration
. The drive can be either on right hand or left hand.
. 1st deck : 2 torch cut grids with divergent opening.
. 2nd deck : side tensioned.
Technical informations
MACHINE WIDHT(M)
LENGTH(M)
AMPLITUDE(mm)
SPEED(RPM)
LUBRICATION
CSB 1238 1.3 2.8 8.5 to 9.5 800 to 900 GREASE
CSB 1528 1.5 2.8 8.5 to 10.5 800 to 900 GREASE
Presentation
. Mechanism : 2 shafts mounted with 4 spherical rollers.bearings.no gear, self synchronisation.
. Linear vibration, inclined at 45°
. Drive : 1 motor per shaft line.motors are mounted on the vibrating body.
. 1st deck : 2 torch cut grids with divergent opening
. 2nd deck : side tensioned deck or deck with rubber pannels bolted or vibrating rods.
EDB scalping screens
Presentation
MACHINE WIDHT(M)
LENGTH(M)
AMPLITUDE(mm)
SPEED(RPM)
LUBRICATION
EDB 1539 1.5 3.9 13 850 OIL BATH
EFB 1844 1.8 4.4 13 850 OIL BATH
Technical informations
CHECK SECOND DECK MOTORS
RUBBER PANNELSVIBRATING BODYSCALPING GRIDS
SUSPENSIONSPRINGS
BELTS
Scalping information
We talk about scalping when we use :
- torch cut grids with divergent opening- vibrating rods
Of course, you have to consider that the split is not so accurate as with a square mesh.
Hypothesis :
The average shape of the blocks from the quarry face can be contained into the followingparallepiped :
FEED
E1 EnEavg E2
Torch cut grids with divergent opening
The blocks move forward on their (C) side.
E1 = minimum opening
E2 = maximum opening
Eavg = average opening = E1 + E2
En = nominal opening = 1,2 x Eavg
2
Use the standard grids
Choose between :
- soft steel - Hardness =110 HB
- anti abrasion steel type HARDOX 400 (Hardness = 400 HB)
D
L = 1.66 D
E =
0.6
6 D
C
A
B
Crushed material Graveled material
Averageopening Eavh
(mm)
NominalopeningEn (mm)
Averagesplit sizeD (mm)
MaximumDimension of theblocks passing
throughL (mm)
Average splitsize
D (mm)
MaximumDimension of the
locks passingthroughL (mm)
37 45 60 75 50 65
50 60 80 100 70 90
65 80 105 130 90 115
80 95 130 160 110 140
100 120 160 200 130 160
120 140 190 240 165 210
140 170 225 280 195 250
160 190 255 320 220 280
Standards grids
Vibrating rods
Advantages :
- Anti-blinding properties (because of self-vibration)- Rods can be replaced individually and easily.- Possibility to change the opening with the same rods.- Tensile strength of the rods = 60 daN/mm2 - Hardness = 170 HB
OPENING
FEED
Disadvantage :
- Do not accept big blocks.
Crushed material Graveled pit material
Opening of therod
(mm)
Averagesplit sizeD (mm)
MaximumDimension of theblocks passing
throughL (mm)
Average splitsize
D (mm)
MaximumDimension of the
locks passingthroughL (mm)
20 25 30 25 30
25 30 35 30 35
30 40 50 35 40
35 45 55 40 45
40 50 60 45 50
45 60 75 50 55
50 65 80 60 70
60 80 100 70 80
70 90 110 80 80
80 105 130 90 100
90 120 150 105 120
100 130 160 115 130
Application
Primary plant where the feed function and the scalping action are implemented by 2 separatedmachines.
Capacities
See table.The data have been determinated depending on :
- information we have got from the sites.- strenght of the machine.- acceleration capability of the mechanism.
Data will be updated depending on new informations and changes.
Capacities of scalping screens
CAPACITIES OF SCALPING SCREENS
MACHINE CSB 1328 CDB 1528 EDB 1539 EDB 1844
Vibrationtype Circular Linear
Maximum stroke (mm) 10.5 10.5 13 13
Feed
Maximum capacity (mm) 350 500 650 1000
Maximum feed size (mm) 800 900 1100 1200
Maximum blocks weight (kg) 800 1100 2000 3000
Maximum feed height (m) 0.4 0.4 0.4 0.4
Minimum average space (mm) 60 60 80 80
1st deckDivergating
grids
Thrus capacity (t/h) 160 180 330 400
Maximum average space (mm) 200 200 200 200
Thrus capacity (t/h) 300 340 500 600
2nd deck
Divergatinggrids
Minimum average space (mm) 50 50
Thrus capacity (t/h) 150 180
Maximum average space (mm) 100 100
Thrus capacity (t/h) 380 450
Vibratingparallel rods
Minimum average space (mm) 25 25
Thrus capacity (t/h) 100 125
Maximum average space (mm) 60 60
Thrus capacity 210 250
Wire squaremesh
Minimum square mesh (mm) 30 30 30 30
Thrus capacity (t/h) 50 55 75 90
100Maximum square mesh(mm)
100 100 100 100
Thrus capacity (t/h) 100 120 150 180
Syntheticsquare mesh
Minimum square mesh (mm) 30 30 30 30
Thrus capacity (t/h) 30 35 50 60
Maximum square mesh (mm) 100 100 100 100
Thrus capacity (t/h) 50 60 75 90
ATV Feeders: ATV 09-40 - ATV 11-50 - ATV 14-65
Description
. Mechanism : 2 shafts mounted with 4 spherical rollers.bearings.1 gear for synchronisation.
. Linear vibration, inclined at 45°
. Drive : 1 motor fixed on the frame.motors are mounted on the vibrating body.
. 1st deck : 2 torch cut grids with divergent opening
. 2nd deck : vibrating rods.
MACHINE WIDHT(M)
LENGTH(M)
AMPLITUDE(mm)
SPEED(RPM) LUBRICATION OPTION
ATV 09.40 0.9 4 10 920 OIL BATH SPEED VARIATION
ATV 11.50 1.1 5 11 820 OIL BATH SPEED VARIATION
ATV 14.65 1.4 6.5 13 750 OIL BATH SPEED VARIATION
ATV Feeders: ATV 06-23 - ATV 08-35 - ATV 11-45
CHAIN CURTAIN
HOPPER
POST
FRAME
UNBALANCE MOTORS SUSPENSION STUDS VIBRATING BODY
Description
. Mechanism : 2 electric vibrating motors.
. Linear vibration, inclined at 35° to 45°
. 1st deck : 2 torch cut grids with divergent opening
. 2nd deck : vibrating rods.
MACHINE WIDHT(M)
LENGTH(M)
AMPLITUDE(mm)
SPEED(RPM) OPTION
ATV 06.23 0.6 2.3 6 1000 SPEED VARIATION
ATV 08.35 0.8 3.5 6 1000 SPEED VARIATION
ATV 09.40 0.9 4 10 1000 SPEED VARIATION
ATV 11.45 1.1 4.5 12 1000 SPEED VARIATION
Capacities of ATV Feeders
CAPACITIES OF ATV FEEDERS
ATV 06.23 08.35 09.40 11.45 09.40 11.50 14.65
Excitator 2 VIBRATION MOTORS1 DOUBLE SHAFT
MECANISM
MAximum stroke (mm) 8 8 10 12 12 13 16
Vibration inclinaison 30° 35° 45° 35° 45° 45° 45°
Maximumfeed
Size (mm) 400 500 600 800 600 850 1200
Capacity (t/H) 90 150 250 450 350 600 1000
1st deck
Minimum average space (mm) 37 50 50 50 50 50 70
Thrus capacity (t/h) 30 50 60 100 60 100 160 200
Maximum average space (mm) 120 120 140 140 140 140 160
Thrus capacity (t/h) 50 80 100 170 100 170 240 300
2nd deck
Minimum average space (mm) 15 16 16 22 16 22 24
Thrus capacity (t/h) 10 30 35 70 35 70 90
Maximum average space ( mm) 30 40 50 50 50 50 60
Thrus capacity (t/h) 15 50 60 110 60 110 160
Scalping area 0.7 0.9 1.1 1.9 1.1 1.9 2.4 3.5
Screening area 0.66 0.85 0.9 1.8 0.9 1.8 2.3
Scalping grids Qty 2 2 2 2 2 2 2 3
Feed hopper 6 11 13 15 13 26 40 to 50
Choice of a screen
Surface calculation
It is based on the knowledge and observations got from sites over decades.At the end, we consider:
theoritical surface = ST
ST = USA x B x C x D x E x F x d x SF
With :
M = split (mm)OS = oversize tonnage (t/h)US = undersize tonnage (t/h)HS = half size tonnage (t/h)A = basic capacity (m3/h/m2)B = oversize percentage factor (of the deck concerned)C = efficiency screening factorD = halfsize percentage factor (of the deck concerned)E = Efficiency screening factor for wet screeningF = deck factord = bulk density (t/m3)SF = free area factor
: crushed
: naturalgravel
A(m3/h / m2
M1,5 A
(t/h) / m2 EFree area
%mm
1.01.42.02.53.13.94.85.76.97.58.18.99.61011111213141415161718192021232731
1.21.72.43.13.84.85.87.08.49.11011121213141516161718192021232425283338
11.251.6
22.5
3.1545
6.37.1
89
1011.212.5
14161820
22.42528
31.535.5
4045506380
100
1.52
2.83.64.65.87.28.811121314141516171819202122242527282931354047
1.82.53.44.45.6
78.81113141517181920212224252627293133343638434956
1.31.41.51.71.8
21.91.81.71.71.61.61.51.41.41.31.31.21.21.11.1
111111111
394148484848444855565856596063636467646769687173707274797979
d=1,5
* Factor A = basic capacityFactor E = efficiency screening factor for wet screening
The percentage of free area are according with average wire wove clothes.
* Factor C = efficiency screening factornormal screening C = 1high efficiency screening C = 0.8light screening C = 1.2
* Factor F = deck factor upper deck F = 12nd deck F = 0.93rd deck F = 0.84th deck F = 0.7
0
10
20
30
40
50
60
70
80
90
100
0.7
0.75
0.8
0.85
0.9
0.95
1
1.05
1.1
1.15
1.2
1.25
1.3
1.4
1.5
1.6
1.7
1.8
1.9
3.53.43.33.23.132.92.82.72.62.5
2.4
2.3
2.2
2.1
2.0
70
80
90
100
0 1.6
10
20
30
40
50
60
0.05
0
0.1
0.15
0.2
0.25
0.3
0.35
0.40.450.50.55
0.6
0.65
0.7
0.75
0.8
0.85
0.9
0.95
1
1.05
1.1
1.15
1.2
1.251.31.351.4
1.551.51.45
B D
* Factor B = oversize percentage factorFactor D = halfsize percentage factor
FREE SCREENING AREA OF NORBERG-BERGEAUD SCREENS
MACHINE DECK
1 2 3 4 1/2
CVB 1020 2 2 2/1.8* 1.8
CVB 1030 3 3 3/2.8* 2.8
CVB 1330 3.8 3.8 3.8/3.6 3.6
CVB 1540 6 6 6 6
CVB 1845 8 8 8 8
CVB 2050 10 10 10 10
CVB 2060 12 12 12 12
ELLIVAR 13 12.3 12.3 12.3 12.3
16 14.9 14.9 14.9 7.3
20 18.7 18.7 18.7 7.3
25 23.8 23.8 23.8
CVDB 1550 7.5 7.5 7.5
1850 9.5 9.5 9.5
CSB 1328 2
1528 2.3
EDB 1539 3
1844 3.6
* SF = area factorFor perforated plates (steel or rubber or polyurethane or else), we must take into account asmaller free area.See the table next page.
* Free screening area of NORDBERG screens.According to them, you finally choose the suitable machine.
The area safety factor must be > 1.2It can be decreased down to 1.1 for ELLIVAR screens.Depending on the flow-sheet, you can play with the safety factor if the split accuracy is notabsolutely required.
* If the 3rd deck is the lowest deck.
Spli(m
Woven wiremesh
Ondap-wiremesh
Polyurethane pannels(Square apertures)
Rubber pannels(Square apertures)
Steel plate pannels(Circular apertures)
Gravel Crushed Gravel Crushed Gravel CrushedSurfacefactor
Gravel CrushedSurfacefactor
Gravel CrushedSurfacefactor
1 1.12 1.25 1 1.2
1.25 1.4 1.6 1.3 1.5
1.6 1.8 2 1.75 2
2 2.24 2.5 2.2 2.5
2.5 2.8 3.15 2.5 3
3.15 3.55 4 3.3 3.5
4 4.5 5 4.2 4.5 5 5.6 0.75 5.5 6.3 0.75 0.75
5 5.6 6.3 5.5 6 6.3 7.1 0.75 6.5 7.5 0.75 0.75
6.3 7.1 8 7 7.5 7.1 8.5 0.75 7.5 8.5 0.75 0.75
7.1 8 9 7.5 8 8.5 9.5 0.75 8.5 9.5 0.75 0.75
8 9 10 9 10 9.5 10.5 0.70 9.5 10.5 0.70 0.70
9 10 11.2 10 11 10.5 11.5 0.70 11 12 0.70 0.70
10 11.2 12.5 11 12 12 13 0.70 12.5 13.5 0.70 0.70
11.2 12.5 13.7 12 13 13.5 14.5 0.70 14.5 15.5 0.70 0.70
12.5 14 15 14 15 14.5 16 0.70 16 17 0.70 0.70
14 16 17 15 16 16.5 18 0.70 18 19 0.70 0.70
16 18 19 18 19 18.5 20 0.65 20 21 0.65 0.65
18 20 21 20 21 20 23 0.65 23 24 0.65 0.65
20 22 23 22 23 22.4 25 0.65 25 26 0.65 0.65
22.4 24 25 24 25 25 28 0.65 27 29 0.65 0.65
25 27 28 27 28 28 31.5 0.65 31.5 33.5 0.65 0.65
28 30 31.5 30 31.5 31.5 35.5 0.65 35 37 0.65 0.65
31.5 34 35.5 34 35.5 35.5 38 0.65 38 40 0.65 0.65
35.5 38 40 38 40 38 40 0.65 43 45 0.65 0.65
40 43 45 43 45 42 45 0.65 50 52 0.65 0.65
45 48 50 48 50 48 50 0.60 55 57 0.60 0.60
50 53 56 53 56 53 56 0.60 60 62 0.60 0.60
56 58 63 58 63 0.55 65 68 0.55 0.55
63 65 70 65 68 0.55 74 76 0.55 0.55
80 85 90 85 90 0.50 98 100 0.50 105 110 0.50
100 105 112 105 112 0.50 115 120 0.50 130 135 0.50
120 0.50 135 140 0.50 160 165 0.50
150 170 175 195 200 0.50
Meshes table
If the motion is withflow:s = 1100 m/h = 0,3 m/s
If the motion is counterflow:s = 800 m/h = 0,22 m/s
CVB and CVDB :Dry process, we must have : D < 3 x apertureWet process, we must have : D < 4 x aperture
ELLIVARDry process, we must have : D < 5 x apertureWet process, we must have : D < 7 x aperture
Bed depth on the deck (at the end)
At the end, we have :
If the motion is withflow:
OSD = with
l.d.S
D = bed depth (m)OS = oversize tonnage (t/h)l = screen width (m)d = bulk density (t/m3)s = material travel speed
(m/h)
Relief deck
It can be required for 2 reasons :- To have a smaller bed depth at the split considered- because of the excessive feed size falling on the deck considered (see the table).
Maximum feed size falling on woven wire mesh
Bulk density = 1,5 ton/m3
Important :
* Increase the data of 20% is suitable for gravel.
* These data are based on the knowledge and the observations got from thesites to keep a «correct» lifetime of screen pannels.
* If it is impossible to follow this table, contact the product department in orderto select a suitable equipment (reinforced, rubbermade...).
Woven wire mesh (mm) Maximum feed size (mm)
1 8
1,25 9,5
1,6 11
2 12,5
2,5 15
3,15 17
4 20
5 23
6,3 27
7,1 29
8 31,5
9 34
10 36
11,2 40
12,5 44
14 47
16 50
18 54
20 58
22,4 63
25 68
28 73
31,5 80
35,5 87
40 92
45 100
50 110
63 125
80 145
100 175
Moisture = H2 0%
This factor is influencing the efficiency of fine screeningWhen the split (M) is less than 10mm, we consider :
*If H2 0% < M 8
nothing special
*If M < H2 0% < M8 4If there is clay content, use stainless cloths.
*If M < H2 0% < M4 2Use anti-blinding stainless cloths
*If M < H2 0% < M2
- use anti-blinding stainless cloths- use ball deck- if there is clay content, screening capability must be checked in laboratory.
*If M < H2 0%wet process is required
Software
The area calculation method has been integrated ina software (running under DOS 3.3 system at least).Starting instruction :
1 - Insert the diskette2 - Type : «SC», <ENTER>3 - You get the general menu
Example :
0-11 = 210 t/h
0-6 = 168 t/h
0-2.5 = 105 t/h
Split at 22
Split at 12
Split at 51
=> Next page, see the print.
14
109
77
336
227
150
350 t/h
SCREEN SELECTION
GENERAL INFORMATION
Reference ............................. :
Customer ............................. :Site ....................................... :
Material ............................. :Notes ................ :
Feed size ............................. : 40.0mmBulk density ............................. : 1.5 t/m3
Humidity percentage ....................... : 3%
AREA CALCULATION
Deck 1 2 3
Split at (mm) 22.0 12.0 5
Screening equipement Woven Woven Woven
Wet process no no no
Natural gravel (%) 0 0 0
Oversize (t/h) 14.0 109.0 77.0
Undersize (t/h) 336.0 227.0 150.0
Half size (t/h) 210.0 168.0 105.0
Theoritical area (m²) 5.95 9.26 13.80
Width for CVB screen (m) 0.13 1.84 3.11
Width for ELL screen (m) 0.08 1.10 1.87
Suitable screen ............................. : Ellivar 16
SCREEN CHOICE
Deck 1 2 3
Area (m²)
- theoritical 5.95 9.26 13.80
- free area 18.70 18.70 18.70
- safety factor 3.14 2.02 1.36
Bed depth (mm)
- calculated 3.23 25.12 17.74
- maximum 110.00 60.00 25.00
- Anti-blinding stainless cloths + ball deck are required for deck n° 3- Determine the clay percentage
Screening surfaces
Application Type Screen
1 - Woven wire
General screening Conventional, high resistance steel wire
CVBCVDB
ELLIVARV
Screening of sticky materials Stainless steel or steel, ripple or straight line,rubber joints (fig.1)Mixed ripple and straight line, rubber joints(fig.2)
Screening fine products and dewatering Straight line wire cloth, rubber joints CVB
2 - Perforated plate
CVDB and ELLIVARin certain cases
Screening large size materials Conventional design with bend endsThickness from 4 to 8 mm (fig.3) Flat platedesign.Thickness from 8 to 16 mm (fig.3) Perforatedplate with stop bars
3 - Rubber or polyurethane screeningcloths
CVBCVDB
ELLIVARScreening of large size material Abrasion resistant rubber screen cloths (fig.4)
Screening of fine material Modular polyurethane (fig.5)Polyurethane (fig.6)
Water sprays
Water flowrates in m³/h per deck for a collector pressure of 2 and 3 bars
SCREEN Type All deck 1st deck2nd - 3nd or
4th deckFeedbox
Pipedimension
CVB
1020 17,5 22,5
Ø 125 PN 101030 28 37
1330 37 45
1540 55 67
1845 62 75
Ø 200 PN 102050 83 102
2060 100 122
CVDB1550 64 78 52 64 24 30
Ø 150 PN 101850 74 90 60 74 24 30
ELLIVAR
13 120 146 105 128 30 37
Ø 200 PN 10
16 149 183 157 192 41 50
20 186 228 223 274 41 50
25 223 273 260 319 56 69
30 260 318 297 364 56 69
B-Screens
Main dimensions ...................................................................... 199Transport dimensions and weights .......................................... 200Supporting loads ...................................................................... 201Optional equipment .................................................................. 202
Main dimensions
A B C D E F
Drawing mm mm mm mm mm mm
B256T 287690 4931 1788 2351 3315 1330 1452
B356T 287834 4931 2078 2351 3315 1330 1752
B280T 287889 5858 2279 2796 3900 1640 1770
B380T 287835 5858 2598 2796 3900 1640 2089
B2100T 292889 6850 2335 2796 4695 1640 1826
B3100T 287836 6850 2655 2796 4695 1640 2146
B
C
A
D
E
F
Transport dimensions and weights
Dimensions (mm)
Drawingnumber
A C H Weight(kg)
B256T 287690 4931 2351 1625 3590
B356T 287834 4931 2351 1915 4240
B280T 287889 5858 2796 2107 6260
B380T 287835 5858 2796 2426 7390
B2100T 292889 6850 2796 2166 7150
B3100T 287836 6850 2796 2486 8290
A F
H
Supporting loads
Static(kN)
Dynamic(kN)
Materialpressuremax.(kN)
Springmin.
lengthwhenloadel(mm)
DWGnumber F1
vert.F2
vert.F1hor.
F1vert.
F2hor.
F2vert.
F1lvert.
F2lvert.
B256T 287690 8,2 9,6 ±0,2 ±1,2 ±0,2 ±1,2 6,3 4,9 251
B356T 287834 9,6 11,2 ±0,3 ±1,4 ±0,3 ±1,4 4,9 3,3 251
B210T 287889 14,2 16,4 ±0,5 ±3,6 ±0,5 ±3,6 10,6 8,4 300
B380T 287835 17,3 18,7 ±0,4 ±3 ±0,4 ±3 7,5 6,1 300
B2100T 292889 16,9 18 ±0,5 ±3,1 ±0,5 ±3,1 8 6 300
B3100T 287836 19,7 20,9 ±0,5 ±3,5 ±0,5 ±3,5 4,6 3,4 300
F2 vert.
F2 hor.
F1 vert.
F1 hor.
Supporting loads per corner (unloaded)
Optional equipment
Underframe
1. Underframe2. Support springs3. Motor trestle4. Support bar
Side wear plates
1. Additional side wear plate2. Additional side wear plate
Washing screen
1. Washing pipe lines
2 3 4 1 2
1
2
Dust encapsulation
1. Rubber seals2. Cover rubbers3. Feed inlet4. Supports
1 2 1 2 1 3
4
B-Feeders
The B-Feeders range ............................................................... 205
The B-Feeders range
C
A B
TypeIndicativeflow rate
(t/h)
Power kW (hp) Rotationspeed(rpm)
DimensionsAppro.
weight (lbs)Hydrauliccontrol
Pulley + drivebelt control
A(mm)
B(mm)
C(mm)
B 10-42-2V 400 22 (30) 15 (20) 450 - 1200 4240 1012 735 3800 (8380)
B 10-52-2V 400 22 (30) 15 (20) 450 - 1200 5190 1012 800 4500 (9920)
B 13-44-2V 550 22(30) 22(30) 450 - 990 4390 1306 795 5200 (11462)
B 13-50-3V 550 22 (30) 22(30) 450 - 1000 5200 1294 1115 8300 (18290)
B 13-56-2V 550 22 (30) 22(30) 450 - 900 5640 1306 800 6200 (13670)
B 16-50-3V 800 37 (50) 37 (50) 450 - 900 5200 1612 1115 9000 (19840)
B 16-56-2V 800 37 (50) 37 (50) 450 - 900 5790 1616 1169 11400 (25130)
B 20-60-2V 1500 55 (75) 55 (75) 450 - 800 6000 2040 1170 15000 (33065)
Washing Plants
SAND RECLAIMING AND DEWATERING................................. 207Technical information ............................................................... 208Dimensions .............................................................................. 209
WASHING BARRELS TYPE LD................................................. 210General data............................................................................. 211Clearance dimensions of washing barrels in metres ............... 212
SAND TREATMENT PLANTS .................................................... 213On site operation ...................................................................... 214To determine the suitable sand units ....................................... 215
WATER CLARIFICATION ........................................................... 216Specifications ........................................................................... 217
SAND RECLAIMING AND DEW ATERING
Technical information
DEA TYPE 520 730 1030 1430 1540
diameter of the wheel mm 2000 3000 3000 3000 4000
Width of the wheel mm 500 700 1000 1400 1500
Surface of tank square m 2,4 4,9 6,1 10,6 16,6
weight of emply machine kg 1700 2920 3840 4700 7220
power of motor kw 1,5 1,5 2,2 3 4
SPEED rpm
fixed speed
minimum speed 1,24 1 1 1 0,83
normal speed 1,5 1,2 1,2 1,2 1
maximum speed 2 1,5 1,5 1,5 1,25
variable speed
range rpm
from 0,6 0,5 0,5 0,5 0,45
to 2,5 2 2 2 1,8
CAPACITY OF EACH MODEL cubic metres per hour
at minimum speed 16 29 42 58 90
at normal speed 20 35 50 70 110
at maximum speed 26 44 62 88 135
WATER REQUIREMENTS cubic metres per hour 60 110 150 210 330
Dimensions
Type A B C D E F G H I J K L M N O
520 2750 1250 1500 1730 574 730 1080 2205 904 1115 1500 570 600 854 884
730 3900 1800 2100 2350 849 1080 1580 3232 1159 1340 2000 870 900 1104 1134
1030 3900 1800 2100 2350 849 1080 1580 3240 1410 1605 2500 870 900 1355 1385
1430 4770 2400 2370 2500 577 818 1780 3275 1900 1900 2210 865 900 940 835
1540 6046 3020 3026 3110 655 1148 2300 4300 2200 2200 2395 1169 1200 1010 885
N NO O
KI JA
B C
L LM M
DE F
GH
WASHING BARRELS TYPE LD
General data
TYPE LD 13.35 16.40 19.50 22.50 25.60 28.70 * 31.80 * 34.90 *
Drum diameter mm 1.300 1.600 1.900 2.200 2.500 2.800 3.100 3.400
Drum length mm 3.500 4.000 5.000 5.000 6.000 7000 8.000 9.000
Total weight kg 4.300 5.000 10.500 12.400 17.400 24.000 32.000 41.000
Power reqd kw 3.7 5.5 15 18.5 30 45 60 90
Max size of feed mm 100 125 150 175 200 225 250 275
Max throughput tph 35 50 110 160 220 290 370 460
Water reqd m³ h 35 60 110 150 220 290 370 460
NB : 1 - Sizes marked * built to order only.NB : 2 - Quoted capacities may vary by + or - 20% dependant upon nature of contaminants in the feed material.
NB : 3 - Specifications can be altered without prior notice in order to benefit from the latest technical developments.
Clearance dimensions of washing barrels in metres
Machine Size A B C D E F G H I J
LD 13.35 1.30 3.50 3.75 0.85 0.80 1.20 1.60 2.00 1.05 1.40
LD 16.40 1.60 4.00 4.25 1.00 0.90 1.30 1.90 2.25 1.15 1.50
LD 19.50 1.90 5.00 5.30 1.15 1.00 1.40 2.20 2.50 1.35 2.10
LD 22.50 2.20 5.00 5.30 1.40 1.30 1.50 2.50 2.75 1.45 2.20
LD 25.60 2.50 6.00 6.30 1.70 1.45 1.60 2.80 3.00 1.50 2.60
LD 28.70 2.80 7.00 7.40 2.00 1.75 1.70 3.10 3.25 1.75 2.90
LD 31.80 3.10 8.00 8.40 2.30 2.00 1.80 3.40 3.50 1.90 3.20
LD 34.90 3.40 9.00 9.40 2.60 2.30 1.90 3.70 3.75 2.05 3.50
* NB : the dimensions given above are approximate and should not be used for civil structural design.
C
B
A D E
J I
F
H
G
SAND TREATMENT PLANTS
On site operation
1) The sand slurry to be treated, is pumped or gravity feed to a tank. (1)
2) At the base of the tank is a pump which pumps the sand slurry under pressure into one (orseveral) cyclone(s) (3) where sand/water separation takes place.
3) Very fine particles and clays are carried to the overflow by reject water, while sand concentratereports to the underflow which flows on to a vibrating table.
The vibrating desander is driven by unbalanced weighted motors and is supplied with fine meshscreens. The sand passes over the screens, separated from water by gravity anf feeds into ahopper . (5) The fines passing through the mesh are recycled into the tank feeding the pump,equipped with an automatic level control. This system allows sand recycling back to the maintank. The outline dimensions and technical characteristics are indicated in the following tablesand drawings. By cross reference to available standard units, all possible combinations can beselected to make treatments units which meet client requirements : double or tripple cyclonecycles, curve correction, fine sand recovery, etc...
GA
D
E
C
F
B
Sand unit : 50 t/h rated
Dry sand productdischarge
Dirty wateroverflow
(1)
FEED
(3)
(2)
(4)
(6)
(5)
GA
D
E
C
F
B
Sand unit : 50 t/h rated
Dry sand productdischarge
Dirty wateroverflow
(1)
FEED
(3)
(2)
(4)
(6)
(5)
N° Sandcapacity
Watercapacity Pump tank
Sand pumpCyclone
type
DryerWeight
Dimensions
Size Motor HP N° Motor HP A B C D E F G
1 10 t/h 35 m3/h 170 x 170 3 " 7,5 300 1 2 x 0,6 1,6 t 2 300 1 450 3 000 1 500 1 700 1 300 2 500
2 20 t/h 95 m3/h 170 x 170 4 " 15 425 1 2 x 0,6 1,8 t 2 300 1 450 3 200 1 500 1 800 1 300 2 650
3 35 t/h 90 m3/h 180 x 200 4 " 18,5 425 2 2 x 1,2 3 t 2 700 1 930 3 100 1 400 1 700 1 200 2 800
4 45 t/h 90 m3/h 180 x 200 4 " 22 550 2 2 x 1,2 3,2 t 2 700 1 930 3 300 1 320 1 670 1 100 3 000
5 60 t/h 150 m3/h 180 x 200 6 " 22 550 7 2 x 2 3,3 t 3 400 2 700 3 700 1 700 2 000 1 400 2 700
6 70 t/h 230 m3/h 180 x 200 6 / 8 " 30 675 7 2 x 2 3,5 t 3 500 1 800 3 900 1 700 2 500 1 500 4 700
7 95 t/h 210 m3/h 200 x 270 6 / 8 " 37,5 675 3 2 x 2,7 4,9 t 3 800 2 000 4 200 2 000 2 800 1 750 5 600
8 120 t/h 300 m3/h 200 x 270 8 " 45 800 9 2 x 2,7 8 t 4 000 2 300 4 400 2 000 2 700 1 550 6 200
9 140 t/h 280 m3/h 230 x 340 8 " 55 800 4 2 x 4 8,3 t 4 660 2 300 4 700 2 180 2 900 1 660 7 200
10 160 t/h 800 m3/h 230 x 370 8 " 75 800 5 2 x 4 8,5 t 4 900 2 300 4 820 2 300 3 100 1 750 7 400
11 200 t/h 800 m3/h 230 x 370 10 " 90 1 000 5 2 x 4 9,1 t 4 900 2 300 4 900 2 300 3 200 1 750 7 500
12 260 t/h 540 m3/h 230 x 440 10 " 90 1 000 11 2 x 6 10,5 t 5 500 2 300 5 550 2 400 3 300 1 800 8 800
13 350 t/h 900 m3/h 240 x 440 12 " 132 2 x 1 000 14 2 x 6 15 t 5 500 2 400 5 550 2 400 3 300 1 800 8 800
To determine the suitable sand units
WATER CLARIFICATION
Specifications
SERIAL N° RATE M3/hØ
NOMINALH A B C
1 340 150 7 m 2 000 2 000 4 000 1 700
1 350 250 9 m 2 000 2 500 4 500 1 700
1 360 370 11 m 2 200 2 500 4 700 1 700
1 370 560 13 m 2 200 2 800 5 000 2 400
1 380 800 16 m 2 200 2 800 5 000 2 400
1 390 1 000 18 m 2 200 3 000 5 200 2 400
1 400 1 200 20 m 2 200 3 000 5 200 2 500
C
Dirty waterfeed
Frost free storageroom
Clearwater
Flocculent
Gallery
Slurrydischarge
Cle
ar w
ater
Sum
p ev
acua
tion
HA
B
Rod mill on pneumatic tyres
Specifications ........................................................................... 219Overall dimensions................................................................... 220
Specifications
MODEL 14X35 16X35 21X35
Crusher dimensions
mm 1.400 1.630 2.100
mm 3.500 3.500 3.500
Motor power kw 75 110 200
kg 9.250 12.150 18.925
Crusher weight
without rods
or motor dry process kg 15.080 18.960 35.000
wet process kg 14.950 18.700 34.600
Rod charge supplied kg 8.940 12.520 22.080
Dimensions - unpacked
m 4.35x1.85x1.95 4.45x2.15x2.25 4.75x2.84x2.84
Chassis m 3.00x2.50x1.70 3.20x2.50x1.80 5.61x3.35x1.88
Overall dimensions
WET PROCESS 5830DRY PROCESS 5450
3920
1000 400
293625t 25t
25t 25t 25tDYNAMIC FORCE
FEEDENTRY
ø 600
DISCHARGE 800
2360
DISCHARGE
ø 7
40
3780
ø 5
00EN
TR
AN
CE
3120
ø 2140
ø 2840
25t 25tDYNAMIC FORCE25t 25t
WET PROCESS 5030 5150
DRY PROCESS 4165 4360
3800 3900
2910 2962
DISCHARGE
DISCHARGE
FEEDENTRY
ø 600
2546
26
65
EN
TR
AN
CE
ø40
0
ø
500
1200 600
1552
1690
ø 6
65
ø 7
40
2585
283
0
ø 1850 ø 2080
ø 1430 ø 1666
3010 3010
1880 1880
800
400
14 x 35 - 16 x 35
21 x 35
Specific conveyors
Swivelling stacker..................................................................... 222Longitudinal stacker ................................................................. 223Pivoting stacker ........................................................................ 225Track-mounted conveyor.......................................................... 227
Swivelling stacker
Conveyor :- Belt width : 800 mm- Head / base drums distance : 57 m- Power : 22 kW- Belt speed : 2.25 m/s- Inclination angle : 12°- Tail axis height : 6.25 m- On the tail screw type tension- Belt type : 40 4 + 2- Trussed structure- Walkways- Head peripheric walkways- Emergency stop cables- Tubular gantry support
Stockpiling :- Stock height : 18 m- Stock radius : 56 m- Top stocks line length : 43 m- Required surface : 78 m x 108 m (included TC)
Swivelling :- Turntable on trackwheels- Pivoting angle : 44°- Pivoting radius : 33.15 m- Wheels trajectory : 25.60 m
Longitudinal stacker
Feed conveyor :- Belt width : 800 mm- Head / base drums distance : 182 m- Power : 60 kW with electrical starter- Belt speed : 3 m/s- Center counter weight belt tension device- Belt type : 50 4 + 2- Ground / beam top distance : 5.7 m
Stockpiling conveyors :- Belt width : 800 mm- Head / base drums distance : 22 m- Power : 30 kW- Belt speed : 3 m/s- Belt type : 25 4 + 2- Inclination angle range : 0° a 24°- Electrical raising winch : 3 tons 4 strands- Motorised pivoting feed hopper- Level sensor at the stockpile top
Stockpiling :- Stockpiles height : 15 m- Stocks axis distance : 46 m- Top stocks line length : 122 m- Required surface : 82 m x 190 m (included feed conveyor)
Gantry :- Gantry height : 17 m- Total moving weight : 40 tons- Wheel-base : 12 m- Travelling by means of 4 geared motors of 1.5 kW each- Able to run with a wind of 72 kmph- Travelling wheels : ø 400 mm- Progressive start and stop achieved by means of frequency variation
with a braking unit
Runway :- Railway gauge : 10 m- Railway length between thrust-blocks : 136 m- Rail 36 kg
Nota :- Whole unit driven by means of a programming controller
Total approximate weight : 90 tons
Pivoting stacker
Stockpiling :- Stock height : 22.5 m- Stock radius : 26.7 m- Required surface : 107 m x 107 m- Top stocks line length : 112 m (240°)- Stockpiling capacity : 85 000 cum
Conveyor :- Belt width : 800 mm- Head / base drums distance : 28 m- Power : 30 kW- Belt speed : 2.25 mps- Center counter weight belt tension device- Inclination angle : 20° (other possible angles 18° to 22°)
Pivoting :- Roller-mounter turntable ø 1595 mm- Brake geared motor power : 1.5 kW speed : 1.74 tpmin- Able to run with a 72 kmph wind- Speed at boom end : 0.52 mps (0.19 tpmin)- Brakes calculated for a 130 kmph wind- Frequency variation with a braking unit
Frame :- Post ø1500 m- Tubular sectional- Walkways for acces to all the mechanical components
Track-mounted conveyor
Conveyor :- Belt width : 1000 mm- Head / base drums distance : 30 m- Power : 11 kW- Belt speed : 1.75 mps- Inclination angle : 6°
Crawler :- Width : track 0.7 m / gauge 2.6 m / total 3.3 m- Length : wheels distance 3.35 m / total 4.3 m- Pressure on the groun < 0.6 bar- Admissible slope 15%
Total weight :26 tons
Belt feeders
Belt feeder length 1.5 m ........................................................... 229Belt feeder length 3 m .............................................................. 230
Belt feeder length 1.5 m
Frame : - Single block frame
Rollers : - Greased for life
Drums : - Rubber coated drum- Counter convex drum
Bearings : - Greased for 25000 h
Belt : - 6 + 2 antiabrasion coating
Drive unit : - MRVSR motorized reducervariable speed drive(variation range from 1 to 6)
or- MRDC motorized reducer
direct current(variation range from 1 to 40)
Options : - Feed chute- Radial-gate- Bars-gate- Tunnel pier-head- Direct current rectifier
Machine : - Fully assemblied and adjustedin our factory
Maximum inclination : 15°
ADB 06.15 08.15 10.15
BELT WIDTH mm 650 800 1000
TRACTION RESISTANCE N/mm 40 40 50
DRUM DIAMETER mm 214 265 344
H mm 620 730 850
R mm 290 320 360
I mm 400 530 650
L mm 500 630 750
M mm 870 1020 1260
N mm 420 420 480
TOTAL WEIGHT kg 730 890 1200
SMALLPRODUCTS
MAXI SIZE mm 40 40 40
MAXICAPACITY
tph 400 600 1000
PkW
MRVSR 4 4 7.5
MRDC 5.3 5.3 8.3
BIGPRODUCTS
MAXI SIZE mm 100 125 160
MAXICAPACITY
tph 120 250 400
PkW
MRVSR 2.2 2.2 4
MRDC
Belt feeder length 3 m
Frame : - Single block frame
Rollers : - Greased for life
Drums : - Rubber coated drum- Counter convex drum
Bearings : - Greased for 25000 h
Belt : - 6 + 2 antiabrasion coating
Drive unit : - MRVSR motorized reducervariable speed drive(variation range from 1 to 6)
or- MRDC motorized reducer
direct current(variation range from 1 to 40)
Options : - Feed chute- Radial-gate- Bars-gate- Tunnel pier-head- Direct current rectifier
Machine : - Fully assemblied and adjustedin our factory
Maximum inclination : 15°
ADB 06.30 08.30 10.30
BELT WIDTH mm 650 800 1000
TRACTION RESISTANCE N/mm 40 40 50
DRUM DIAMETER mm 214 265 344
H mm 550 650 780
R mm 290 320 360
I mm 460 574 750
L mm 1250 1250 1250
M mm 870 1020 1260
N mm 420 420 480
TOTAL WEIGHT kg 900 1000 1360
SMALLPRODUCTS
MAXI SIZE mm 40 40 40
MAXICAPACITY
tph 160 250 400
PkW
MRVSR 4 4 7.5
MRDC 5.3 5.3 8.3
BIGPRODUCTS
MAXI SIZE mm 100 125 160
MAXICAPACITY
tph 60 100 150
PkW
MRVSR 2.2 2.2 4
MRDC
Laboratory test
Abrasivity test ........................................................................... 232Abrasivity and crushability indexes .......................................... 233Abrasivity scale ........................................................................ 234Crushability scale ..................................................................... 235The abrasivity limits.................................................................. 236Dynamic fragmentation test ..................................................... 237Impact crushability test............................................................. 238Impact W.I. (table) .................................................................... 239
Abrasivity test
Sample : - Weight: 500 G- Crushed material- Gradation : minus 6 mm - plus: 4 mm
Principle of the test :
A rectanguar steel plate is plunged into the sample and is spinning for 5 mm.Wo = weight of the plate before the test (G)W1 = weight of the plate after the test (G)
Result: ABR = (Wo - W1) * 1000/0.5 (Grammes per tons)
Remark :
The abrasivity index is given in grammes of steel per metric ton of material (and notmanganese steel).
Abrasivity and crushability indexes
1- Sample:crushed and dried 4 / 6.3 mm size of product (500g)
2- Before testing, paddle weight: Mb (g)
3- Test: 5 min at 4500 rpm
4- After testing, paddle weight: Ma (g)
5- Abrasivity index determination: ABR =
6- After testing, sample is screened at 1.6 mm sieve.Weight of product passing the sieve: Mp (g)
7- Crushability index determination: BR =
(Mb - Ma) x 1000
0.5(g/t)
Mp500
x 100 (%)
Abrasivity scale
ABR 0 500 1000 1500 2000
Abrasivity very low low medium high very high
MAINROCKTYPES
LIMESTONE
BASALT
SANDSTONE
GRANITE
QUARTZITE
Crushability scale
CR % 0 25
Crushabilityverydifficult
medium
50 75 100
easyveryeasy
The abrasivity limits
A = ABRASIVITY
PRIMARY APPLICATION
- Manganese steel hammers A<250 G/T
SECONDARY APPLICATION
- Manganese steel hammers A<250 G/T- Hammers in chrome cast iron 250<A<600 G/T
If A>600, consult our machines Department.
Remark :Cast iron hammers utilization proscribes the presence of metallic particles in theCrusher (it is absolutely necessary to install a metal detector on the conveyor feedingthe Crusher.
Dynamic fragmentation test
Sample : - Weight: 350 G- Gradation : 4/6.3 mm or 6.3/10 mm or 10/14 mm
Principle of the test :
The sample of the material is put into a steel cylinder (sizes: diameter 102 mm, height52 mm, thickness 10 mm). A mass (14 kg) is falling down several times on the samplefrom a height of 40 cm. The number of the blows depends of the gradation of thesample:
GRADATION
After the necessary number of blows, the sample is screened at 1.6 mm.
M = WEIGHT OF MATERIAL > 1.6 mm (grammes)
FD = (350 - M) * 100 / 350
GRADATION
Number of blows
4/6.3 6.3/10 10/14
16 22 28
Impact crushability test
1- Ten to fifteen samples of approximately 3 inch to 2 inch dimensions with two naturalparallel or near parallel side of 2 to 3 inch widths are selected.
2- Each sample piece is placed on a pedestal and struck simultaneously by twoopposing hammers of standard size and shape.
3- The height of the hammers are increased until the sample is broken and the totalfoot-pounds (A) of force are recorded. The width (W) of the sample at the fracture isrecorded.
4- The Work Index is calculated from the equation:
5- Two W.I. are recorded: The maximum W.I. and the average W.I. of the samplestested.
2.59A
W
Sp. Gr.
Impact W.I. (table)
Very Hard Maximum Average
Trap Rock 38.79 29.75Gabbro Rock 41.21 24.68Trap Rock 37.84 30.99Quartzite 24.51 19.81Granite (Fine Grain) 28.44 20.76
Hard
Lead-Zinc 21.14 13.37Limestone 22.27 15.82Granite 18.10 13.68Granite 22.06 16.76Marble 19.71 13.47
Medium
Copper Ore 12.23 8.01Andesite 14.19 9.12Granite (Large Grain) 19.38 10.33Copper Ore 18.77 10.15Marble 18.65 9.40Magnetite 18.13 9.38
Soft
Limestone 9.00 4.87Iron Ore 8.30 4.73Shale 8.44 6.07Bauxite 15.62 6.22Bauxite Clay 10.49 5.79